JP2001087849A - Molten metal supplying device in casting machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily correspond to variable setting of molten metal supplying quantity into a horizontal injection sleeve while securing the quantity highly precisely. SOLUTION: A fixed quantity storing chamber 73 for storing the necessary quantity of the molten metal for one time of injection is formed on the upper part of a piston 59 in the state of existing at a specified position C by moving a measuring stroke S of the piston 59 from a measuring reference position B to the specified position C. In this state, the molten metal 29 in a molten metal furnace 31 is transported into the fixed quantity storing chamber 73 from a molten metal supplying tube 33 through a connecting path 53 by an electromagnetic pump 35. The excess molten metal transported into the fixed quantity storing chamber 73 overflows into the side of connecting path 53 over a weir 51. The molten metal in the fixed quantity storing chamber 73 measured to the specified quantity, is made to flow down and is supplied into the injection sleeve 25 by descending the piston 59 to an expanding chamber 77.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot water supply apparatus for a casting machine for transferring molten metal in a molten metal furnace to a horizontal injection sleeve communicating with a mold cavity.

[0002]

2. Description of the Related Art Conventionally, there is a cold chamber type die casting machine as a casting machine, for example, as shown in FIG. 3 (see Japanese Patent Application Laid-Open No. 62-110855). This is because the horizontal injection sleeve 5 is mounted on the fixed die 1 and the fixed die plate 3 to which the fixed die 1 is attached, and the horizontal injection sleeve 5 and the molten metal holding the molten metal 7 are held. The furnace 9 is connected by a hot water supply pipe 11.

An electromagnetic pump 13 for transferring the molten metal 7 to the horizontal injection sleeve 5 is provided around the hot water supply pipe 11 near the molten metal holding furnace 9. The passage between the mold cavity 17 formed between the fixed mold 1 and the movable mold 15 and the horizontal injection sleeve 5 is filled with 100% molten metal in the horizontal injection sleeve 5. Is installed.

When the plunger tip 21 advances while the sensor 19 detects the molten metal, the molten metal in the lateral injection sleeve 5 is supplied to the mold cavity 17 to form a predetermined casting.

[0005]

By the way, in the above-mentioned die casting machine, the hot water supply port 5a of the horizontal injection sleeve 5 is provided so that high pressure is not applied at the time of injection.
Preferably, the plunger tip 2 is in the retracted position shown in FIG.
Must be located on one side. For this reason, it is difficult to make the stroke S of the plunger tip 21 shorter than the state shown in FIG. 3, and there is a problem in coping with the variable hot water supply amount. Also,
As a sensor 19 for detecting the molten metal filled in the horizontal injection sleeve 5, there is no sensor having good responsiveness to withstand high temperature and high pressure, and there is a problem that the hot water supply amount cannot be secured with high accuracy. Further, since the hot water supply port 5a is formed below the horizontal injection sleeve 5, there is a possibility that solidified pieces of the molten metal may remain and adhere to the hot water supply port 5a.

On the other hand, there is a die-casting machine hot water supply device provided with a hot water supply port on the upper side of a horizontal injection sleeve in order to improve the drainage of the hot water supply port and prevent the above-mentioned solidified pieces from remaining and adhering (for example, Japanese Patent Application Laid-Open No. HEI 9-110572). 3-146250).

[0007] However, even in the publication described in this publication, since no specific numerical value is set when the molten metal is supplied quantitatively to the horizontal injection sleeve, the accuracy of hot water supply is inferior. It is necessary to try the work a plurality of times, resulting in deterioration of workability.

Accordingly, an object of the present invention is to make it possible to easily set a hot water supply amount variably while ensuring the hot water supply amount to the horizontal injection sleeve of the molten metal with high accuracy.

[0009]

In order to achieve the above object, the present invention is directed to a horizontal injection sleeve for connecting a molten metal in a molten metal furnace to a mold cavity through a hot water supply pipe by a transfer means. In a hot water supply device of a casting machine for supplying to a hot water supply port provided at an upper portion of the hot water supply pipe, a fixed-quantity supply unit is provided between the hot water supply pipe and the horizontal injection sleeve to accommodate a predetermined amount of molten metal and supply the molten metal to the horizontal injection sleeve. The fixed-quantity supply unit is configured such that a piston sliding space is formed across a weir with respect to a communication path whose lower end communicates with the hot water supply pipe, and the piston movably provided in the piston sliding space is located at a predetermined position. A fixed amount accommodation chamber for accommodating a prescribed amount of molten metal is formed between the piston and the upper end position of the weir, and the piston descends and enters between the piston sliding space and the hot water supply port. , Fixed quantity storage room and supply It is constituted of a piston accommodation space mouth and communicates is provided.

[0010] According to the hot water supply apparatus of the casting machine having such a configuration, the molten metal in the molten metal furnace is sent to the fixed amount supply section via the hot water supply pipe by the transfer means. In the fixed amount supply section, the molten metal rises up the communication path, passes over the weir, and flows into the fixed amount storage chamber. At this time, the piston is at the specified position, and after the inflowing molten metal is filled in the fixed amount storage chamber, the transfer operation of the molten metal by the transfer means is stopped, and when the molten metal level in the communication path decreases, At the same time, the excess molten metal in the fixed quantity storage chamber overflows the weir and overflows to the communication path side, and the level of the molten metal in the fixed quantity storage chamber becomes substantially equal to the upper end position of the weir.

According to a second aspect of the present invention, in the configuration of the first aspect, the molten metal level in the molten metal furnace is set at a position lower than the upper end of the weir.

According to the above construction, when the transfer operation of the molten metal by the transfer means is stopped after the fixed amount chamber is filled with the molten metal, the level of the molten metal in the communication path becomes equal to the level of the molten metal in the molten metal furnace. At the same time, the molten metal in the fixed amount storage chamber overflows the weir and overflows to the side of the connecting road.

According to a third aspect of the present invention, in the configuration of the first or second aspect, a level sensor for detecting a level of the molten metal in the fixed quantity storage chamber is provided, and the level sensor detects the level of the molten metal. When detecting that the metal level of the metal is substantially equal to the upper end position of the weir, a control means for stopping the transfer operation of the molten metal by the transfer means is provided.

According to the above configuration, the transfer of the molten metal to the fixed quantity storage chamber is stopped when the molten metal level in the fixed quantity storage chamber becomes substantially equal to the upper end position of the weir.

According to a fourth aspect of the present invention, in the configuration of any one of the first to third aspects, the piston accommodating space has a structure in which the inner peripheral wall forms a gap with the outer periphery of the piston when the piston enters. is there.

According to the above configuration, when the piston descends and enters the piston accommodating space in a state where the fixed amount of the molten metal is accommodated in the fixed amount accommodating chamber, the molten metal is transferred to the inner peripheral wall of the piston accommodating space and the outer periphery of the piston. Flows from the hot water supply port to the injection sleeve.

According to a fifth aspect of the present invention, in any one of the first to fourth aspects of the present invention, a stroke sensor for detecting a vertical position of the piston is provided. Control means for stopping the movement of the piston when it is detected that the piston has moved by the weighing stroke up to the measuring stroke is provided.

According to the above configuration, the piston stops in a state where the piston has moved from the measurement reference position to the specified position, and in this state, the piston sliding space between the piston and the upper end position of the weir serves as the fixed amount accommodation chamber. .

According to a sixth aspect of the present invention, in the configuration of any one of the first to fourth aspects of the present invention, a rotary encoder for detecting a vertical position of the piston is provided, and the rotary encoder is configured to measure the piston in advance. A control means is provided for stopping the movement of the piston when it has reached a specified position separated by the measuring stroke from the reference position.

According to the above configuration, the piston stops when it reaches the specified position separated by the measuring stroke from the measuring reference position, and in this state, the piston sliding space between the piston and the upper end position of the weir. Becomes the fixed amount accommodation room.

According to a seventh aspect of the present invention, in the configuration of the fifth or sixth aspect, the measurement reference position is located below the prescribed position.

According to the above configuration, the piston moves up from the weighing reference position toward the specified position or moves toward the specified position separated by the weighing stroke from the weighing reference position, whereby the weighing operation is performed. Done.

According to an eighth aspect of the present invention, in the configuration of the fifth or sixth aspect, the measurement reference position is located at a height corresponding to the upper end of the weir.

According to the above configuration, the piston moves down from the height position corresponding to the upper end position of the weir, or moves toward the specified position separated by the measuring stroke with respect to the measurement reference position. Work is done.

[0025]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is an overall configuration diagram of a hot water supply device of a casting machine showing an embodiment of the present invention, and shows an example in which the invention is applied to a die casting machine as a casting machine. A horizontal injection sleeve 25 extending in the horizontal direction is mounted on a mold (not shown) of the die casting machine. A plunger tip 27 which moves forward and backward in the figure by an injection cylinder (not shown) is housed in the horizontal injection sleeve 25,
By the forward movement of the plunger tip 27 to the left, the molten metal in the lateral injection sleeve 25 is filled in the mold cavity.

On the other hand, one end of a horizontally arranged hot water supply pipe 33 is connected to a molten metal furnace 31 containing a molten metal 29 made of an aluminum alloy, a magnesium alloy, or the like. Is provided with an electromagnetic pump 35 as transfer means. The electromagnetic pump 35 is provided with an electromagnetic coil 37 disposed around the hot water supply pipe 33 and a core 39 disposed inside the hot water supply pipe 33, and is driven and controlled by a control circuit 41 as control means.
The molten metal 29 inside the hot water supply pipe 33 is transferred leftward in the drawing. A heater 43 is provided around the hot water supply pipe 33.

A cover 44 covering the upper opening of the melting furnace 31 has
An in-furnace level sensor 45 is provided. The in-furnace level sensor 45 is, for example, an optical sensor that receives the reflected light of the irradiated laser beam on the level and detects the level of the level. The detection signal is input to the control circuit 41. The control circuit 41 receives the detection signal from the in-furnace level sensor 45 and sets the level of the molten metal 29 between L ₁ and L ₂ , which is the hot water supply range, for example, to replenish the molten metal (not shown). By operating the apparatus, the molten metal
Replenish. Incidentally, molten metal surface level L ₃ are those when Haiyu the molten metal in the hot water supply pipe 33 in such shutdown and maintenance of the apparatus.

A hot water supply port 47 is formed in the upper portion of the right side end of the horizontal injection sleeve 25 in the drawing. Between the injection sleeve 25 having the hot water supply port 47 and the hot water supply pipe 33, a fixed quantity supply unit 49 is provided. The fixed-quantity supply unit 49 is provided inside the body 50 with
3 and a piston sliding space 55 are respectively formed. The communication path 53 has a lower end communicating with the other end of the hot water supply pipe 33,
The upper end communicates with the piston sliding space 55 via the space 57. Height A of the upper end of the weir 51 is set to a position higher than the melt surface level L ₁ of the molten metal in the molten furnace 31.

In the piston sliding space 55, a piston 59 is provided.
The piston rod 61 connected to the upper end thereof is connected to the lower part of the coupling 65 through a lid 63 covering the upper opening of the space 57. The upper part of the coupling 65 is connected to an actuator 69 via a connecting rod 67. The actuator 69 is driven and controlled by the control circuit 41, and moves the piston 59 up and down. This piston 5
9 is detected by a stroke sensor 71 installed on the lid 63. The detection signal of the stroke sensor 71 is input to the control circuit 41, and the control circuit 41 controls the drive of the actuator 69 based on the input signal.

The piston 59 moves upward from the measurement reference position B at a position B indicated by a solid line, and moves the piston 59 to a predetermined position C indicated by a two-dot chain line, for example. It is supplied to the moving space 55. At this time, the piston sliding space 55 above the piston 59 forms a fixed amount accommodation chamber 73, and supplies the fixed amount accommodation room 73 until the upper end position A of the weir 51 and the molten metal level become substantially the same position. The amount of the molten metal used corresponds to the amount of the molten metal used in one injection (casting) operation.

The quantity Q of the molten metal in the fixed quantity storage chamber 73 corresponding to the height P between the positions A and C is expressed by the following equation.

Q = πd ² P / 4 (d: radius of the piston sliding space 55) If the height between the measurement reference position B and the position A is T, the measurement stroke S by the piston 59 is S = T-
P (where T> P).

The molten metal level at the same position as the upper end position A of the weir 51 is detected by a molten metal level sensor 75 attached to the lid 63. The detection signal is input to the control circuit 41, and the control circuit 41 stops the operation of the electromagnetic pump 35 in response to the input of the detection signal.

An expansion chamber 77 as a piston accommodating space is formed below the piston sliding space 55 so as to communicate therewith. In the expansion chamber 77, a gap 79 is formed between the inner peripheral wall and the outer circumference of the piston 59 in a state indicated by a hot water supply position D in which the piston 59 has entered the expansion chamber 77 (shown by a two-dot chain line).
A tapered portion 81 is formed at the lower portion of the expansion chamber 77 so that the passage area becomes smaller toward the lower side, and a nozzle portion 83 at the lower end communicates with the hot water supply port 47.

An outer peripheral wall of the body 50 below the upper end of the weir 51 is covered with a case 85, and a heater 87 is installed on the outer peripheral surface of the case 85. In addition, an inert gas supply hole 89 is formed in the lid 63, and an inert gas G such as an argon gas or a nitrogen gas is appropriately supplied to the inside, whereby the inside becomes an inert gas atmosphere and the molten metal is formed. To prevent oxidation.

Next, the operation of the hot water supply apparatus of the casting machine having the above configuration will be described with reference to the flowchart shown in FIG. First, when the supply amount of the molten metal necessary for one injection (casting) operation is input (step 301), the measuring stroke S of the piston 59 corresponding to the input supply amount is calculated (step 303). That is, the measuring stroke S corresponds to the moving stroke of the piston 59 from the measuring reference position B to the specified position C.

Thereafter, when the weighing reference position B is confirmed by the stroke sensor 71 (step 305), the actuator 69 is operated (step 307), and the piston 59 is raised to start the weighing stroke S (step 309). . The stroke sensor 71 detects that the piston 59 has reached the specified position C, and when the measuring stroke S is completed (step 311), the actuator 69 is stopped (step 313), and the electromagnetic pump 35 is subsequently operated (step 311). 315).

The operation of the electromagnetic pump 35 causes the molten metal furnace 31
The molten metal inside reaches the connecting path 53 via the hot water supply pipe 33,
Furthermore, it flows over the weir 51 and flows into the fixed amount storage chamber 73.
When the molten metal level in the fixed amount accommodation chamber 73 reaches the position A, the molten metal level sensor 75 detects this (step 317), and based on this, the operation of the electromagnetic pump 35 stops (step 319). . Thereby, the electromagnetic pump 3
5 is avoided.

When the operation of the electromagnetic pump 35 is stopped, the molten metal in the communication path 53 decreases until the level of the molten metal becomes equal to the level of the molten metal in the melting furnace 31. Excess molten metal overflows the weir 51 and overflows to the communication path 53 side. As a result, the level of the molten metal in the fixed amount storage chamber 73 is reliably held at the position A, and accurate measurement can be performed, thereby improving the accuracy of hot water supply.

Next, the actuator 69 is operated (step 321), and the piston 59 descends and enters the expansion chamber 77 until the hot water supply position D is reached. When the stroke sensor 71 detects this hot water supply position D (step 32).
3), the actuator 69 stops (step 32)
5). After the actuator 69 stops, the control circuit 41
The hot water supply wait timer built in the CPU operates (step 32).
7) While the timer is running, the fixed quantity storage chamber 73
The entire amount of the molten metal inside flows down from the gap 79 formed between the piston 59 and the inner peripheral wall of the expansion chamber 77, and is supplied into the injection sleeve 25 via the nozzle 83 and the hot water supply port 47.

That is, as the operation (counting) time of the hot water supply waiting timer, at least the time required for the entire amount of the molten metal in the fixed quantity storage chamber 73 to flow down to the injection sleeve 25 is required. When the operation of the hot water supply waiting timer is completed (step 329), the actuator 69 is operated again (step 331) to raise the piston 59. When the stroke sensor 71 detects that the piston 59 has reached the measurement reference position B (step 333), the actuator 69 stops (step 335), and then the step 305 is performed.
And the subsequent operations are repeated.

After the operation of the hot water supply waiting timer is completed in step 329, that is, after the entire amount of the molten metal is supplied to the horizontal injection sleeve 25, the casting operation is performed in parallel with the operation in step 331 and thereafter. That is, the plunger tip 27 advances (step 337), and the molten metal in the lateral injection sleeve 25 is filled in the mold cavity. The molten metal filled in the mold cavity is held under pressure (Step 339), and then the plunger tip 27 is retracted (Step 341), and the post-casting process ends (Step 3).
43).

When changing the amount of hot water supply, step 301
By changing the input value of the supply amount of the molten metal in the above, the specified position C with respect to the measurement reference position B is changed, and in response to this, the fixed amount capable of storing the amount of the molten metal according to the changed input value. The accommodation room 73 is formed. In this way, it is possible to easily cope with the setting and variation of the hot water supply amount.

In the embodiment described above, the measurement reference position B is set below the specified position C, but may be set at a position corresponding to the position A at the upper end of the weir 51.

Further, a motor may be used as the actuator 69, and an absolute type rotary encoder instead of the stroke sensor 71 may be attached to this motor. In this case, the rotary encoder moves to the measurement reference position B.
If the distance is always read, the operation of confirming the measurement reference position B (step 305) in the flowchart of FIG. 2 becomes unnecessary, and the piston 59 moves from the state where the hot water supply position D is reached (step 329) to the measurement stroke ( However, the measuring stroke in this case is a distance from hot water supply position D to specified position C.), and may directly move to specified position C. That is, step 30
The operation of 5,331,333,335 becomes unnecessary, and work efficiency is improved.

Further, the transfer means for transferring the molten metal is not limited to the electromagnetic pump 35, and other means such as a mechanical pump may be used.

[0048]

As described above, according to the first aspect of the present invention, the excess molten metal flowing into the fixed amount storage chamber above the piston at the specified position overflows to the communication path side by the weir, so that the molten metal is melted. The metal can be accurately measured and the accuracy of hot water supply is improved, and the volume of the fixed amount accommodation chamber can be changed by appropriately setting the prescribed position of the piston, so that the hot water supply amount can be easily changed.

According to the second aspect of the present invention, the molten metal level in the molten metal furnace is lower than the upper end of the weir. Just by stopping the transfer operation of the metal, the molten metal level in the communication path is lowered so as to be equal to the molten metal level in the melting furnace. It can overflow to the connecting road side via the weir.

According to the third aspect of the present invention, the transfer of the molten metal to the fixed quantity storage chamber is stopped when the molten metal level in the fixed quantity storage chamber becomes substantially equal to the upper end position of the weir. Therefore, useless operation by the transfer means can be avoided.

According to the fourth aspect of the present invention, the specified amount of molten metal accommodated in the fixed amount accommodating chamber is moved downward by the piston into the piston accommodating space, so that the inner peripheral wall of the piston accommodating space and the outer periphery of the piston are separated. The water can be supplied from the hot water supply port to the injection sleeve through the gap.

According to the fifth aspect of the present invention, the stroke sensor for detecting the vertical position of the piston is provided, and the control means controls the movement of the piston from the measurement reference position to the specified position for the measurement stroke. The volume of the fixed amount storage chamber above the piston after the measuring stroke operation can be made to be able to store a specified amount of molten metal.

According to the sixth aspect of the present invention, the rotary encoder for detecting the vertical position of the piston is provided, and the control means controls the movement of the piston to the specified position separated by the measuring stroke from the standard measuring position. , The volume of the fixed quantity storage chamber above the piston after reaching the specified position,
It is possible to accommodate a specified amount of molten metal.

According to the seventh aspect of the present invention, the piston moves upward from the measurement reference position to reach the reference position, or reaches the specified position separated by the measurement stroke from the measurement reference position, thereby causing the piston to move. The volume of the upper fixed-quantity storage chamber can be set to a state in which a specified amount of molten metal can be stored.

According to the eighth aspect of the present invention, the piston moves downward from the measurement reference position corresponding to the upper end position of the weir to reach the specified position, or is separated from the measurement reference position by the measurement stroke. By reaching the position, the volume of the fixed amount storage chamber above the piston can be set to a state in which a specified amount of molten metal can be stored.

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram of a hot water supply device of a casting machine showing an embodiment of the present invention.

FIG. 2 is a flowchart showing an operation of the hot water supply device of the casting machine in FIG. 1;

FIG. 3 is a sectional view of a cold chamber type die casting machine showing a conventional example.

[Explanation of symbols]

 Reference Signs List 25 Horizontal injection sleeve 29 Molten metal 31 Molten furnace 33 Hot water supply pipe 35 Electromagnetic pump (transfer means) 41 Control circuit (Control means) 47 Hot water supply port 49 Fixed supply section 51 Weir 53 Communication path 55 Piston sliding space 59 Piston 71 Stroke sensor 73 Fixed-quantity accommodation chamber 75 Fluid level sensor 77 Expansion chamber (piston accommodation space) 79 Gap A Upper end position of weir B Measurement reference position C Specified position S Measurement stroke

Claims (8)

[Claims] 1. A hot water supply apparatus for a casting machine for supplying molten metal in a molten metal furnace through a hot water supply pipe by a transfer means to a hot water supply port provided at an upper portion of a horizontal injection sleeve connected to a mold cavity. A fixed-quantity supply unit is provided between the pipe and the horizontal injection sleeve to accommodate a predetermined amount of molten metal and supply the molten metal to the horizontal injection sleeve. A piston sliding space is formed, and a predetermined amount of molten metal is accommodated between the piston and the upper end position of the weir in a state where the piston movably provided in the piston sliding space is at a predetermined position. A fixed amount accommodation chamber is formed, and a piston accommodating space is provided between the piston sliding space and the hot water supply port, where the piston descends and enters into the fixed amount accommodation room and the hot water supply port. It is characterized by Hot water supply equipment for casting machine. 2. The hot water supply device for a casting machine according to claim 1, wherein the level of the molten metal in the molten metal furnace is set at a position lower than the upper end of the weir. 3. A level sensor for detecting the level of molten metal in the fixed volume storage chamber, wherein the level of the molten metal is substantially equal to the upper end position of the weir. 3. The hot water supply apparatus for a casting machine according to claim 1, further comprising control means for stopping the transfer operation of the molten metal by the transfer means when the fact is detected. 4. The hot water supply apparatus for a casting machine according to claim 1, wherein the piston housing space has a gap formed between the inner peripheral wall and the outer periphery of the piston when the piston is inserted. . 5. A stroke sensor for detecting a vertical position of a piston, wherein when the stroke sensor detects that the piston has moved by a measuring stroke from a measuring reference position to a specified position, the movement of the piston is detected. 2. The control device according to claim 1, further comprising control means for stopping the operation.
A hot water supply apparatus for a casting machine according to any one of claims 1 to 4. 6. A rotary encoder for detecting a vertical position of a piston, wherein the rotary encoder detects that the piston has reached a specified position separated by a measuring stroke from a predetermined measuring reference position. 5. The hot water supply apparatus for a casting machine according to claim 1, further comprising control means for stopping the movement of the piston. 7. The hot water supply apparatus for a casting machine according to claim 5, wherein the measurement reference position is below a prescribed position. 8. The hot water supply apparatus for a casting machine according to claim 5, wherein the measurement reference position is at a height position corresponding to an upper end of the weir.