JP3213803U - Release agent supply system - Google Patents

Abstract

Disclosed is a mold release agent supply system that can adjust the concentration of a mold release agent stock solution more accurately with a diluting solution and supply it to a die casting mold in a simple configuration. In a release agent supply system, release agent preparation means (2) for preparing a release agent having a predetermined concentration with a diluting solution is disposed in a cylindrical housing (20). The first piston 24 of the first pump means 26 and the second piston 36 of the second pump means 32 are connected by an operating rod 60, and these two pistons are moved together in the same direction. By doing so, the discharge of the release agent stock solution from the first pump means 26 and the discharge of the diluent from the second pump means 32 are alternately performed and mixed in the mixing chamber 44, A release agent having a predetermined concentration was formed. [Selection] Figure 2

Description

  The present invention relates to an improvement of a release agent supply system, and in particular, supplies a release agent obtained by diluting a release agent stock solution to a predetermined dilution ratio with a diluent such as industrial water to a die casting apparatus. The present invention relates to a release agent supply system for a die casting mold for spraying the inner surface of a cavity of the die casting mold.

  Conventionally, in die casting of a predetermined molten metal such as aluminum, a predetermined liquid release agent is supplied to the die casting mold and the release agent is sprayed on the inner surface of the mold cavity. A mold supply system is provided, and the mold release agent supplied through such a mold release agent supply system is sprayed in advance on the inner surface of the mold cavity of the die cast mold prior to casting the target die cast product. Can be applied. As such a release agent supply system (release agent supply device), generally, as shown in FIG. 5 of JP-A-2003-144877, a water-soluble release agent stock solution is used as industrial water or the like. Pumps and valves for quantitative supply of the release agent stock solution and diluent are provided so that the release agent (liquid) diluted to a predetermined concentration with the diluent can be prepared and supplied to the die casting mold. In the mixing tank, stirring is performed using a stirring device, and the release agent sent from the mixing tank to the liquid storage tank by a pump passes through the discharge cylinder to the mold cavity of the mold. It is configured so that it can be sprayed.

  In addition, in Japanese Patent Laid-Open No. 2003-144877, as is clear from FIG. 1, after the release agent stock solution and the diluted solution are respectively introduced into a special mixer by a pump, they are installed on the downstream side thereof. It has been clarified a system that is introduced into a static stirrer and is uniformly mixed and diluted to form a target release agent and then supplied to a die casting mold. .

  Further, in JP 2013-71141 A, as a release agent dilution supply device, a release agent stock solution tank, a mixing tank, and a storage tank are provided, and a float disposed in the mixing tank and the storage tank respectively. The release means is diluted by controlling the opening and closing of the valve means disposed in each air pipe, or the diluted release agent can be supplied to the storage tank, and the release is performed. A structure has been clarified so that the agent can be supplied without electrical control.

  However, in these conventional release agent supply systems or apparatuses, each pump for supplying the release agent stock solution and diluent is independently driven and controlled, and the liquid flow path Various valve means for opening and closing and valve means for adjusting the flow rate are provided, and these valve means are designed to be opened and closed by electric control, and a mixing tank, a mixer and a stirrer are separately provided. The system itself has a problem that the system itself is complicated because it is arranged or a structure in which a float and an air pipe are separately arranged, thereby causing an increase in system price. In addition, the mold release agent is subject to variations in the dilution concentration of the mold release agent stock solution, and when the pressure of industrial water generally used as the diluent changes, the flow rate of the diluent changes, so that the mold release agent Stock solution rare Were those inherent problems such as to change the concentration.

JP 2003-144877 A JP 2013-71141 A

  Here, the present invention has been made in the background of such circumstances, and the problem to be solved is that the concentration of the release agent stock solution is more accurately adjusted with a diluent in a simple configuration. Then, it is providing the mold release agent supply system which enabled it to supply to a die-casting metal mold | die.

  And, in order to solve the above-mentioned problems, the present invention can be suitably implemented in various aspects as listed below, and each aspect described below can be implemented in any combination. It can be adopted. It should be noted that aspects or technical features of the present invention are not limited to those described below, and can be recognized based on the technical concept disclosed in the description of the entire specification and the drawings. Should be understood.

  In view of the above, the present invention provides a release agent supply system in which a release agent prepared to a predetermined concentration is first guided through a supply line and sprayed onto the cavity surface of a die casting mold in order to solve the above-described problems. In the above, a release agent stock solution supplying means for supplying a release agent stock solution used for the preparation of the release agent, and a release agent stock solution supplied from the release agent stock solution supplying means are diluted to a predetermined concentration. Diluting liquid supply means for supplying a diluting liquid and a release agent stock solution supplied from the release agent stock solution supplying means with a diluent supplied from the diluting liquid supply means to obtain a predetermined concentration. A release agent preparation means that prepares a release agent and delivers it to the supply line, and the release agent preparation means is provided on one end side of the tubular housing (a). To form a first pump chamber between the one end. The first piston that is slidably moved with respect to the inner surface of the housing discharges a predetermined amount of the release agent stock solution supplied from the release agent stock solution supply means to the first pump chamber. And (b) an inner surface of the housing which is provided on the other end side of the cylindrical housing and forms a second pump chamber between the other end portion. Second pump means for discharging a predetermined amount of diluent supplied from the diluent supply means to the second pump chamber by a second piston that is slidably moved against the second pump chamber; and (c) the cylindrical shape. The release agent stock solution and the diluent, which are provided between the first piston and the second piston in the housing and are discharged by the first and second pump means, respectively, are mixed together. A mixture in which a predetermined concentration of release agent is formed And (d) an operating rod for connecting the first piston of the first pump means and the second piston of the second pump means to move the two pistons in the same direction in conjunction with each other. And the discharge of the release agent stock solution from the first pump means and the discharge of the diluent from the second pump means are alternately performed by the reciprocating movement of the operating rod, and the mixing is performed. The gist of the release agent supply system is that the release agent having the predetermined concentration is formed by mixing in a chamber.

  In addition, according to one of desirable embodiments of the release agent supply system according to the present invention as described above, a diluent introduction chamber into which a diluent under a predetermined pressure is introduced from the diluent supply means is provided in the housing. The second piston is provided on the opposite side of the second pump chamber from the second piston, and is configured such that the second piston is moved by the diluent under the predetermined pressure introduced into the diluent introduction chamber. The first piston connected via the actuating rod can be moved by the movement of the second piston.

  According to still another preferred aspect of the release agent supply system according to the present invention, the second piston in the second pump means is located on the opposite side of the second pump chamber from the mixing chamber. And a portion of the second piston that is in contact with the mixing chamber and a portion that is in contact with the diluent introduction chamber and a portion of the second piston chamber that is in communication with the second pump chamber. A fluid passage hole and a diluent introduction chamber side fluid passage hole are formed, and further, a mixing chamber side valve means and a diluent introduction chamber side valve means for opening and closing the two fluid passage holes, respectively, are provided, and A switching mechanism for switching the opening and closing operations of the two valve means in opposite directions at the closest and farthest positions of the two pistons to the other end side of the housing; By actuation In the closest position, the dilution liquid introduction chamber side valve means is opened and the mixing chamber side valve means is closed, whereas in the most separated position, the dilution liquid introduction chamber side valve means is closed. The liquid introduction chamber side valve means is operated to be closed, and the mixing chamber side valve means is configured to be opened.

  Furthermore, according to another preferred embodiment of the release agent supply system according to the present invention, the mixing chamber is provided on the opposite side of the first piston of the first pump means from the first pump chamber. Is disposed, and the release agent stock solution in the first pump chamber is allowed to flow into the mixing chamber with respect to the first piston, but the flow of the liquid in the opposite direction is blocked. A check valve means is provided.

  In addition, according to the present invention, advantageously, there is further provided discharge amount variable means capable of changing the discharge amount of the release agent stock solution in the first pump means.

  In the release agent supply system according to the present invention, in the release agent supply line, a liquid storage tank in which the release agent sent from the release agent preparation means is stored and held is provided in the release agent supply line. The structure arrange | positioned so that it may be located downstream from a mold preparation means will be employ | adopted advantageously. Here, the liquid storage tank desirably has a cylindrical shape, and preferably has an arcuate bottom surface or a tapered bottom surface. By adopting the shape of these liquid storage tanks, the formation of corners on the inner surface of the liquid storage tank is reduced as much as possible. By preventing the generation of microorganisms, it is possible to enjoy the advantage that the degradation of the release agent performance can be advantageously avoided.

  Thus, in the release agent supply system according to the present invention, the release agent preparation means for mixing the release agent stock solution and the diluent to prepare the release agent of a predetermined concentration is the release agent stock solution. The first piston in the first pump means that discharges a predetermined amount of the second piston and the second piston in the second pump means that discharges a predetermined amount of the diluted liquid are connected by an operating rod and interlocked with each other. By being moved in the same direction, the pump operation of the respective pump means is performed, so that the pump operation of these two pump means can be performed reliably, and the pump means Since no control means such as electric control for operating the pump is required, it can be greatly simplified in terms of equipment, and the cost of the equipment can be advantageously reduced. In addition, since the release agent stock solution and the dilution solution can be discharged quantitatively by the pump operation of the two pump means, the release agent stock solution can be diluted more accurately with the dilution solution. As a result, the concentration of the release agent supplied from the supply line can be adjusted more accurately.

  In such a configuration according to the present invention, a diluent supplied under a predetermined pressure, such as industrial water, is used as the diluent, and the second piston in the second pump means is driven by the predetermined pressure of the diluent. The second pump means and the first pump means interlocked with the second pump means can be automatically operated without requiring any other power or driving force. As a result, the driving of the first pump means and the second pump means can be simplified, and the release agent supply means can be provided at a lower cost. It will be.

It is whole explanatory drawing which shows the arrangement | positioning form of each apparatus in an example of the mold release agent supply system according to this invention. It is a cross-sectional schematic explanatory drawing which shows an example of the mold release agent preparation apparatus used as a mold release agent preparation means in the mold release agent supply system according to this invention. 2 is an explanatory view schematically showing one of switching mechanisms for switching the opening and closing operations of two valve members in opposite directions in the release agent preparation apparatus shown in FIG. (B) shows an AA cross section in (a), and (c) shows another form of the operation. In the release agent preparation apparatus shown in FIG. 2, the two valve members are switched by the switching mechanism to prevent the diluent from flowing into the second pump chamber, and from the second pump chamber to the mixing chamber. FIG. 6 is a cross-sectional explanatory view showing a state in which the discharge of the diluted liquid is allowed. FIG. 5 is a cross-sectional explanatory view showing a state in the middle of discharging the diluent from the second pump chamber to the mixing chamber in the operating state of the release agent preparation apparatus shown in FIG. 4. From the operating state of the release agent preparation device shown in FIG. 5, the discharge of the diluent from the second pump chamber is prevented, while the diluent is allowed to flow into the second pump chamber. FIG. FIG. 7 is a cross-sectional explanatory view showing a state in which the flow of the diluent into the second pump chamber has further advanced in the operating state of the release agent preparation device shown in FIG. 6. FIG. 3 is an enlarged explanatory view showing an example of a discharge amount varying means arranged in the first pump means in the release agent preparation apparatus shown in FIG. 2, wherein (a) is an enlarged view in a sectional form shown in FIG. 2. It is explanatory drawing, (b) is explanatory drawing which shows the state of the side view in (a). FIG. 3 is a cross-sectional explanatory view showing a stroke form of a first piston that maximizes the discharge amount of the release agent stock solution in the first pump means in the release agent preparation apparatus shown in FIG. 2. It is explanatory drawing which shows the example from which the liquid storage tank used in the mold release agent supply system shown by FIG. 1 differs, (a) is explanatory drawing which shows an example of a liquid storage tank in the form of a perspective view, b) It is explanatory drawing which shows the bottom part in the cross section about the other example of a liquid storage tank.

  Hereinafter, in order to clarify the configuration of the present invention more specifically, embodiments of the present invention will be described in detail with reference to the drawings.

  First, in FIG. 1 which is an overall explanatory view showing an example of a release agent supply system (apparatus) according to the present invention, a release agent preparation device 2 which is a release agent preparation means for preparing a release agent of a predetermined concentration is provided. A stock solution tank 4 as a release agent stock solution supply means is connected, and a water-soluble release agent stock solution having a high viscosity and stored in the stock solution tank 4 is used as a release agent preparation device. 2 can be supplied. On the other hand, a diluent source 6 as a diluent supply means is also connected to the release agent preparation device 2 so that a diluent for diluting the release agent stock solution to a predetermined concentration can be supplied. . Here, industrial water is used as the diluting liquid, and industrial water as the diluting liquid is guided to the release agent preparing device 2 through the supply pipe under a predetermined water pressure. In the release agent preparation device 2, the release agent stock solution supplied from the stock solution tank 4 is diluted with industrial water as a diluent introduced from the diluent source 6 to obtain a release agent having a predetermined concentration. After the preparation, the liquid is sent to the supply line 8 and the liquid release agent obtained by the dilution is stored in the liquid storage tank 10. The release agent in the liquid storage tank 10 is pressurized by the pump 12, sprayed from the spray nozzle 16 under the control of the control valve 14, and applied to the inner surface of the molding cavity of the die casting mold 18. It has come to be.

  In this case, the release agent preparation device 2 is provided on one end side (here, the bottom side) in the cylindrical housing 20 as shown in FIG. A first pump means 26 having a first piston 24 slidably moved with respect to the inner surface of the cylindrical housing 20 forming the first pump chamber 22 therebetween is provided. Specifically, the cylindrical housing 20 is composed of an upper large-diameter portion 20a whose upper end is closed and a lower small-diameter portion 20b. And the small diameter part 20b is comprised from the outer side cylinder part 21a which continues from the large diameter part 20a, and the inner side cylinder part 21b screwed in by this, The stock solution tank 4 via the non-return valve 28 in the lower end part The mold release agent stock solution in the stock solution tank 4 is allowed to flow into the first pump chamber 22 while being released from the first pump chamber 22 toward the stock solution tank 4 side. Outflow (back flow) of the drug stock solution is prevented. Further, the first piston 24 is also provided with a check valve 30 in a passage that passes through the first piston 24, and the release agent stock solution in the first pump chamber 22 is supplied to the large-diameter portion of the cylindrical housing 20. While allowing discharge to the 20a side, the inflow of liquid from the large diameter portion 20a side into the first pump chamber 22 can be prevented. Therefore, when the first piston 24 is slidably moved with respect to the inner surface of the small diameter portion 20b, the release agent stock solution introduced into the first pump chamber 22 from the stock solution tank 4 is Through the check valve 30 of the piston 24, it is discharged to the large diameter portion 20 a side of the cylindrical housing 20.

  On the other hand, the second pump means 32 is provided on the upper end side in the upper large-diameter portion 20a of the cylindrical housing 20, and forms a second pump chamber 34 between the upper end portion. The second piston 36 is provided, and is slidably moved with respect to the inner surface of the large-diameter portion 20a of the cylindrical housing 20 so as to be supplied from the diluent source 6 into the second pump chamber 34. A predetermined amount of industrial water as a diluting solution is allowed to be discharged. Specifically, inside the large diameter portion 20a of the cylindrical housing 20, an inner cylindrical portion 38 that rises integrally from the bottom portion is erected and disposed, and the inner cylindrical portion 38 and the large diameter portion are arranged. An outflow passage 40 penetrating the lower portion of 20a is provided and opened in the inner cylindrical portion 38. The outflow passage 40 is connected to the supply line 8 and prepared in the release agent preparation apparatus 2. The release agent can be guided to the liquid storage tank 10. The second piston 36 is configured to be slidably moved to the inner surface of the inner cylindrical portion 38 together with the inner surface of the large-diameter portion 20a of the cylindrical housing 20, whereby the second piston 36 is configured. A space between the large-diameter portion 20a and the inner cylindrical portion 38, which is located on the opposite side of the piston 36 from the second pump chamber 34 and outside the inner cylindrical portion 38, serves as a diluent introduction chamber 42. The industrial water that is formed and used as the diluent from the diluent source 6 is supplied under a predetermined water pressure. On the other hand, an internal space of the inner cylindrical portion 38 located on the opposite side of the second pump chamber 34 at a portion entering the inner cylindrical portion 38 of the second piston 36 is formed as a mixing chamber 44. The small-diameter portion 20b and the outflow path 40 can be communicated with each other.

  The second piston 36 of the second pump means 32 includes a bottomed cylindrical portion 36a that is coaxially inserted into the inner cylindrical portion 38, and an outer flange that extends radially outward from the upper opening thereof. The outer flange portion 36b is provided with an upper seal 46b, and the bottom outer peripheral surface of the bottomed cylindrical portion 36a is provided with a lower seal 46a. , 46b can be allowed to allow sliding movement in a liquid-tight state with respect to the inner cylindrical portion 38 and the large diameter portion 20a. Further, the bottom portion 36c of the second piston 36 is provided with a lower liquid passage hole 48a which is a mixing chamber side liquid passage hole for allowing the second pump chamber 34 and the mixing chamber 44 to communicate with each other. The flange portion 36b is provided with an upper liquid passage hole 48b as a liquid diluent introduction chamber side liquid passage hole for allowing the second pump chamber 34 and the diluent introduction chamber 42 to communicate with each other. A lower valve member 50a serving as a mixing chamber side valve means and an upper valve member 50b serving as a diluent introduction chamber side valve means are disposed so as to be able to open and close the respective 48b.

  Further, in the bottomed cylindrical portion 36a of the second piston 36, the lower valve member 50a and the upper valve member 50b described above are used to open and close the lower liquid passage hole 48a and the upper liquid passage hole 48b. A switching device 52 is provided. Further, a switching rod 54 penetrating such a switching device 52 and the bottom 36c of the second piston 36 and capable of moving by a predetermined distance in the vertical direction is provided, and is radially inward from the lower end of the inner cylindrical portion 38. When the lower end and upper end of the switching rod 54 come into contact with the stopper portion 38a protruding in the direction and the ceiling inner surface of the large diameter portion 20a of the cylindrical housing 20, the switching rod 54 is predetermined in the axial direction thereof. It can be moved a distance.

  Here, in the switching device 52, as shown in FIG. 3, one end of the drive member 56 having the long hole 56a is connected to the switching rod 54, while the other end is the lower valve. The plate spring 58 has such a structure that it is positioned between two operating rods 57a, 57b provided at a connecting portion between the member 50a and the upper valve member 50b and having a predetermined interval. In the form of being bent in the 56 long holes 56 a, both ends thereof are fixed to stationary members in the switching device 52. Further, when the switching rod 54 is prevented from further lowering or rising at the lowermost position or the uppermost position where the switching rod 54 comes into contact with the inner surface of the ceiling of the stopper portion 38a or the large diameter portion 20a, The leaf spring 58 is moved as shown in FIGS. 3 (a) and 3 (b) by moving the drive member 56 relatively upward or downward relative to the drive member 56. As shown in FIG. 3C, the bent downward state is changed to the upward bent state and held in that state, or the leaf spring 58 is bent and held in the opposite direction. Will be. In addition, when the drive member 56 moves up and down, the drive member 56 pushes and moves the two actuating rods 57a and 57b up and down after a predetermined distance of movement (association), whereby the lower valve member 50a and Simultaneous upper and lower movements of the upper valve member 50b are induced, so that alternate opening and closing operations can be performed. When the lower valve member 50a and the upper valve member 50b are operated as described above, when the urging force due to the curved form of the leaf spring 58 does not act on the valve members, the water pressure of the diluent (industrial water) By acting on the members, the closed state of the fluid passage holes by the valve members is maintained.

  And the center part of the bottom part 36c in the bottomed cylindrical part 36a of the 2nd piston 36 in the 2nd pump means 32 of such a structure, and the center part of the 1st piston 24 in the 1st pump means 26 The operating rod 60 is connected to each other, and the operating rod 60 moves in the axial direction, in other words, in the vertical direction in FIG. The piston 36 can be moved in the same direction (upward or downward) in conjunction with the piston 36. That is, by the reciprocating movement of the operating rod 60 in the axial direction, the discharge operation of the release agent stock solution in the first pump means 26 and the discharge operation of industrial water as the diluting liquid in the second pump means 32 are alternately performed. As a result, the discharged release agent stock solution and industrial water are mixed in the mixing chamber 44 and guided to the liquid storage tank 10 through the outflow passage 40.

  Specifically, in the state shown in FIG. 2, the release agent preparation device 2 has the switching device 52 as shown in FIGS. 3A and 3B, and the lower side of the second piston 36. While the liquid passage hole 48a is closed by the lower valve member 50a, the upper liquid passage hole 48b is released from being closed by the upper valve member 50b, so that the diluent introduction chamber is opened. 42, industrial water having a predetermined pressure is caused to flow into the second pump chamber 34 from the upper liquid passage hole 48 b, whereby the second piston 36 flows into the second pump chamber 34. The water is moved downward in the figure by the water pressure of industrial water. On the other hand, in the first pump means 26, since the first piston 24 is connected to the second piston 36 by the operating rod 60, the first piston 24 is moved downward, As a result, the release agent stock solution present in the first pump chamber 22 is discharged into the mixing chamber 44 through the check valve 30.

  Next, when the switching rod 54 is also lowered as the second piston 36 is lowered, the lower end portion thereof comes into contact with the stopper portion 38a. In this state, the second piston 36 is further lowered. As a result, the switching rod 54 is raised relative to the second piston 36, so that in the switching device 52, as shown in FIG. Accordingly, the lower valve member 50a and the upper valve member 50b are moved upward, and as shown in FIG. 4, the lower valve member 50a and the upper valve member 50b are moved upward. The liquid hole 48a is changed from the closed state by the lower valve member 50a to the open state, while the upper liquid passage hole 48b is closed by the upper valve member 50b. And in such a state, since the predetermined pressure by the water pressure of the industrial water in the diluent introduction chamber 42 is acting on the 2nd piston 36, the 2nd piston 36 is moved upwards. Thus, the industrial water in the second pump chamber 34 is discharged into the mixing chamber 44 through the lower liquid passage hole 48a. On the other hand, in the first pump means 26, the first piston 24 is also moved upward by the upward movement of the second piston 36, whereby a suction operation is induced, and the first pump chamber is moved. In this case, the release agent stock solution is allowed to flow from the stock solution tank 4 through the check valve 28 into the stock solution 22. In addition, as shown in FIG. 5, the suction operation of the release agent stock solution by the first pump means 26 is stopped when the first piston 24 comes out from the inner cylindrical portion 21b in the small diameter portion 20b, and thereafter. The mold release agent stock solution is held in the inner cylinder part 21b by its high viscosity.

  Then, from the state shown in FIG. 4, through the state shown in FIG. 5, the second piston 36 is automatically moved upward by the action of the water pressure of industrial water in the diluent introduction chamber 42. Then, after the upper end portion of the switching rod 54 is brought into contact with the inner surface of the ceiling portion of the large-diameter portion 20a of the cylindrical housing 20, the second piston 36 further moves upward, so that the switching rod 54 is moved to the first position. Accordingly, in the switching device 52, the driving member 56 presses the leaf spring 58 downward, and the switching member 52 is moved downwardly as shown in FIGS. 3 (a) and 3 (b). As shown in FIG. 2, the leaf spring 58 is displaced into a form bent downward. As a result, the lower valve member 50a and the upper valve member 50b are moved downward, and as shown in FIG. 6, the lower liquid passage hole 48a is closed by the lower valve member 50a. On the other hand, the upper liquid passage hole 48b is opened from the closed state by the upper valve member 50b to be in the open state. Thus, industrial water is introduced into the second pump chamber 34 from the diluent introduction chamber 42 into the second pump chamber 34 through the upper liquid passage hole 48 b, and accordingly, the second piston 36. Is lowered, and after the state shown in FIG. 7, the state shown in FIG. 2 is obtained again. Further, from the state shown in FIG. 7, when the second piston 36 is lowered, the first piston 24 connected by the actuating rod 60 is again plunged into the inner cylindrical portion 21b in the small diameter portion 20b. Thus, the release agent stock solution accommodated in the inner cylindrical portion 21 b is discharged through the check valve 30 and introduced into the mixing chamber 44.

  As described above, in the release agent preparation apparatus 2, a predetermined amount of the release agent stock solution is obtained from the first pump chamber 22 in the first pump means 26 by repeating the state shown in FIGS. While being discharged into the mixing chamber 44, a predetermined amount of industrial water as a diluting solution is discharged from the second pump chamber 34 of the second pump means 32. And discharge of such a mold release agent undiluted | stock solution and industrial water connects the 1st piston 24 and the 2nd piston 36 by the operating rod 60, these pistons 24 and 36 interlock | cooperate, and it is the same direction. Can be carried out alternately from the point where they are driven, and can be introduced into the mixing chamber 44, thereby effectively mixing the release agent stock solution and the industrial water. Thus, the concentration of the obtained release agent can be adjusted more accurately and sent to the liquid storage tank 10.

  Moreover, in the release agent preparation apparatus 2 according to the present embodiment, the driving of the second piston 36 (piston operation) in the second pump means 32 is automatically performed using the water pressure of industrial water used as the diluent. The second piston 36 and the first piston 24 in the first pump means 26 are connected by the actuating rod 60 and interlocked, so that the first pump means 26 in the first pump means 26 Since the pump operation of the first piston 24 is also performed simultaneously, it is necessary to use a special drive source or drive device for the piston operation of the first piston 24 and the second piston 36. As a result, the configuration of the mold release agent preparation device 2 can be advantageously simplified, and a separate pump means, quantitative supply mechanism, mixer, etc. By no longer necessary to place, it is becoming an be obtained allowed effectively reduce the cost of the apparatus.

  In the present invention, the release agent preparation apparatus 2 as described above is further provided with a discharge amount variable means capable of changing the discharge amount of the release agent stock solution in the first pump means 26. It is desirable that the concentration of the release agent adjusted in the mixing chamber 44 can be changed appropriately. Specifically, as shown in FIG. 2 and FIGS. 4 to 7, the outer cylindrical portion 21 a and the inner cylindrical portion 21 b constituting the small-diameter portion 20 b of the cylindrical housing 20 are screwed to each other and the outer cylindrical portion 21 a. A structure in which the discharge amount of the release agent stock solution is adjusted such that the amount of protrusion of the first piston 24 inserted into the inner cylinder portion 21b is changed according to the degree of screwing of the inner cylinder portion 21b. However, it can be adopted.

  Further, as the discharge amount varying means, a structure as shown in FIG. There, the inner cylinder part 21b is structured to be able to slide into the outer cylinder part 21a, and fixed to the inner cylinder part 21b with respect to the screw part formed on the outer peripheral surface of the outer cylinder part 21a. It is also possible to screw the movable cylinder 62 and control the amount of axial movement of the inner cylinder portion 21b, and hence the discharge amount of the release agent stock solution, depending on the degree of screwing of the movable cylinder 62. is there. In this case, as shown in FIG. 8 (b), the scale 64 shows the screwing amount of the movable cylinder 62 with respect to the outer cylinder portion 21a and the axial movement amount of the inner cylinder portion 21b. Accordingly, it is desirable that the discharge amount of the release agent stock solution, and thus the degree of dilution by mixing with the diluent, can be easily recognized.

  Furthermore, in the illustrated release agent preparation apparatus 2, in order to maximize the discharge amount of the release agent stock solution from the first pump means 26, for example, as shown in FIG. By screwing into the cylinder part 21a as deeply as possible and arranging it so that the upper end of the inner cylinder part 21b reaches the base part of the outer cylinder part 21a, the inside of the inner cylinder part 21b of the first piston 24 is increased. The stroke can be maximized, whereby the discharge amount of the release agent stock solution can be maximized.

  Meanwhile, in the release agent supply system shown in FIG. 1, a liquid storage tank 10 is disposed on the supply line 8 on the downstream side of the release agent preparation device 2, thereby releasing the release agent. The liquid mixture of the release agent stock solution and the industrial water delivered from the apparatus 2 can be stored in the liquid storage tank 10. The presence of such a liquid storage tank 10 is intended to make the diluted release agent uniform, and to ensure the amount of release agent necessary for spraying on the mold 18, and further to the inside thereof. It is desirable that an appropriate stirring means is provided as necessary.

  Further, as the liquid storage tank 10, a normal rectangular tank can be used, but in the present invention, in particular, as shown in FIG. Further, a structure having an arc-shaped bottom surface as shown in FIG. 10B or a structure having a tapered bottom surface is advantageously employed. By adopting such an inner or bottom structure, it is possible to reduce the residence of the release agent in the tank as much as possible, to suppress or prevent the generation of bacteria, etc., and to improve the quality of the release agent. Can be secured.

  As described above, one of the representative embodiments of the present invention has been described in detail. However, this is merely an example, and the present invention is not limited to a specific description according to such an embodiment. It should be understood that this is not to be construed as limiting.

  For example, the mold release agent preparation device 2 in the illustrated embodiment automatically activates the second piston 36 by using the water pressure of industrial water used as a diluent, and is connected by the operation rod 60, At the same time, the piston of the first piston 24 is also operated, so that a predetermined amount of industrial water as a release agent stock solution and a diluting solution are alternately discharged and mixed in the mixing chamber 44. The intended release agent can be prepared, and the piston operation of the first piston 24 and the second piston 36 by such an operating rod 60 is performed using an external driving force. It is also possible to do so.

  In addition, both the structure of the first pump means 26 and the second pump means 32 in the mold release agent preparation device 2 and the structure of the switching device 52 are understood here. In order to facilitate the process, a simplified structure is illustrated, but a known structure having a similar function can be appropriately adopted, and various changes, modifications, improvements, and the like can be made based on the knowledge of those skilled in the art. It is possible to add.

  Although not enumerated one by one, the present invention can be implemented in a mode with various changes, modifications, improvements, etc. based on the knowledge of those skilled in the art, and such a mode of implementation is It goes without saying that any one of them belongs to the category of the present invention without departing from the spirit of the present invention.

2 Release agent preparation device 4 Stock solution tank 6 Diluent source 8 Supply line 10 Liquid storage tank 12 Pump 14 Control valve 16 Spray nozzle 18 Mold 20 Cylindrical housing 20a Large diameter part 20b Small diameter part 21a Outer cylinder part 21b Inner cylinder part 22 1st pump chamber 24 1st piston 26 1st pump means 28,30 Check valve 32 2nd pump means 34 2nd pump chamber 36 2nd piston 36a Bottomed cylindrical part 36b Outer flange part 38 Inner cylindrical portion 38a Stopper portion 40 Outflow passage 42 Diluent introduction chamber 44 Mixing chamber 46a Lower seal 46b Upper seal 48a Lower fluid passage 48b Upper fluid passage 50a Lower valve member 50b Upper valve member 52 Switching device 54 Switching rod 56 drive member 56a oblong hole 57a, 57b actuating rod 58 leaf spring 60 actuating rod 62 moving cylinder

Claims (8)

A release agent supply system in which a release agent prepared to a predetermined concentration is guided through the supply line and sprayed onto the cavity surface of the die casting mold,
Release agent stock solution supplying means for supplying a release agent stock solution used for preparing the release agent, and for diluting the release agent stock solution supplied from the release agent stock solution supplying means to a predetermined concentration Diluting solution supplying means for supplying a diluting solution and a releasing agent stock solution supplied from the releasing agent stock solution supplying means are diluted with a diluting solution supplied from the diluting solution supplying means to release a mold having a predetermined concentration. A release agent preparation means for preparing an agent and delivering it to the supply line,
And the release agent preparation means,
In the cylindrical housing, a first pump which is provided on one end side thereof and forms a first pump chamber with the one end portion and is slidably moved with respect to the inner surface of the housing. A first pump means for discharging a predetermined amount of the release agent stock solution supplied from the release agent stock solution supply means to the first pump chamber by the piston of
In the cylindrical housing, a second pump chamber is provided on the other end side to form a second pump chamber between the other end portion and is slidably moved with respect to the inner surface of the housing. Second pump means for discharging a predetermined amount of diluent supplied from the diluent supply means to the second pump chamber by two pistons;
A release agent stock solution and a diluent, which are provided between the first piston and the second piston in the cylindrical housing and are discharged by the first and second pump means, respectively, are mixed. A mixing chamber in which a release agent having a predetermined concentration is formed,
An operating rod for connecting the first piston of the first pump means and the second piston of the second pump means and moving the two pistons in the same direction in conjunction with each other;
And the discharge of the release agent stock solution from the first pump means and the discharge of the diluting liquid from the second pump means are alternately performed by the reciprocating movement of the operating rod, and mixing is performed in the mixing chamber. A mold release agent supply system configured to form the mold release agent having the predetermined concentration by caulking.   A diluent introduction chamber into which a diluent under a predetermined pressure is introduced from the diluent supply means is provided on the opposite side of the second piston chamber from the second piston in the housing. The second piston is moved by the diluent under the predetermined pressure introduced into the introduction chamber, and the second piston is connected by the movement of the second piston via the operating rod. The mold release agent supply system according to claim 1, wherein one piston is configured to be moved.   The second piston in the second pump means is in contact with the mixing chamber and the diluent introduction chamber on the side opposite to the second pump chamber, and the mixing chamber of the second piston A mixing chamber side liquid passage hole and a dilution liquid introduction chamber side liquid passage hole communicating with the second pump chamber are formed in a portion in contact with the dilution liquid introduction chamber and a portion in contact with the dilution liquid introduction chamber, respectively. Mixing chamber side valve means and dilution liquid introduction chamber side valve means for opening and closing the liquid holes, respectively, are disposed, and the closest approach position and the most distant position relative to the other end side of the housing of the second piston The switching mechanism has a switching mechanism for switching the opening and closing operations of the two valve means in opposite directions, and the switching means of the switching mechanism opens the diluent introduction chamber side valve means at the closest position. As While the mixing chamber side valve means is configured to be closed, the diluent introduction chamber side valve means is closed and the mixing chamber side valve means is opened at the most separated position. The mold release agent supply system according to claim 2, wherein the release agent supply system is configured to be caulked.   The mixing chamber is disposed on the opposite side of the first pump means to the first pump chamber of the first piston, and the first pump chamber is located with respect to the first piston. 4. A check valve means for preventing the flow of the mold release agent stock solution from flowing into the mixing chamber but preventing the flow of the liquid in the opposite direction is provided. 2. A mold release agent supply system according to item 1.   5. The release unit according to claim 1, further comprising discharge amount variable means capable of changing the discharge amount of the release agent stock solution in the first pump means. 6. Mold supply system.   In the release agent supply line, a liquid storage tank that stores and holds the release agent delivered from the release agent preparation means is disposed on the downstream side of the release agent preparation means. The mold release agent supply system according to any one of claims 1 to 5, wherein the release agent supply system is provided.   The mold release agent supply system according to claim 6, wherein the liquid storage tank has a cylindrical shape.   The mold release agent supply system according to claim 6 or 7, wherein the liquid storage tank has an arcuate bottom surface or a tapered bottom surface.

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