KR102344720B1 - Hydrostatic device with non-contact agitation conveying system - Google Patents

Abstract

The present invention relates to a hydrostatic pressure device provided with a non-contact agitation conveying system to smoothly circulate a pressurized medium, and more specifically, to a hydrostatic pressure device with a non-contact agitation conveying system, which comprises: an external vessel having an insertion groove formed therein, and a first toothed portion formed in the insertion groove to protrude therefrom; an upper cap having a second toothed portion protruding from an outer circumferential surface to correspond to the first toothed portion, and rotationally coupled to the insertion groove; a magnet drive coupled to a lower portion of the upper cap and operated in a non-contact manner by magnetic force with an inner vessel inserted into the insertion groove; and a circulation portion operated by the magnet drive to circulate the pressurized medium supplied to the insertion groove. Compression molding can be performed at a uniform temperature by minimizing the temperature deviation of the pressurized medium inside the insertion groove, that is the inner vessel.

Description

Hydrostatic device with non-contact agitation conveying system

The present invention relates to a hydrostatic pressure device that is provided with a non-contact stirring transfer system to smoothly circulate a pressurized medium. More specifically, the present invention is an external vessel in which an insertion groove is formed and a first toothed part protrudes into the insertion groove. and an upper cap rotatably coupled to the insertion groove, and a second toothed portion corresponding to the first toothed portion protrudingly formed on the outer circumferential surface, and the inner vessel coupled to the lower portion of the upper cap and inserted into the insertion groove, non-contact by magnetic force By comprising a magnet drive operated in this way and a circulation part operated by the magnet drive to circulate the pressurized medium supplied to the insertion groove, the temperature deviation of the pressurized medium inside the insertion groove, that is, the inner vessel, is minimized to be uniform It is a technical field related to a hydrostatic pressure device equipped with a non-contact stirring transfer system that enables compression molding to be performed at one temperature.

In general, a hydrostatic pressure device, in other words, an isostatic pressure device, injects a gas or fluid, that is, a pressurized medium, into the inner vessel in a state where a workpiece is placed inside the inner vessel, and performs compression molding by the pressure of the gas or fluid. It is used for molding powders such as metal or ceramics, especially for manufacturing chip parts, and is also used for sterilization of food.

A conventional isostatic pressurizing device includes an insulator forming a processing chamber for accommodating a workpiece, a pressure vessel covering the insulator, a heating device for heating the pressure vessel, and the pressure vessel in Korean Patent Laid-Open No. 10-2007-0112718. A pressure medium supply device capable of supplying a pressure medium is provided therein, a pressure medium introduction space capable of introducing a pressure medium is provided between the heat insulator and the pressure vessel, and the processing chamber is pressurized through a communication hole formed in the upper portion of the heat insulator. Disclosed is an "isotropic pressure pressurization device" that communicates with the medium introduction space and is configured such that the pressure medium supply device communicates with the pressure medium introduction space through a pressure medium introduction port formed at the bottom of the pressure vessel.

The conventional isostatic pressure device heats a pressure medium with a heating device and supplies it to the pressure medium introduction space, and also supplies the heated pressure medium to the pressure vessel, so that compression molding of the workpiece can be performed in a heated state. .

However, in the conventional isostatic pressure device, the upper cover and the lower cover must be coupled to the upper and lower parts of the body to seal the pressure vessel, which is a fastening that is coupled to each other so that the upper cover and the lower cover are not separated from the pressure vessel, that is, the body. Since it is necessary to separately install an outer vessel that has a structure or supports them so that they are not separated, the structure is complicated and the manufacturing cost increases. have.

In addition, in the conventional isostatic pressure device, if the upper cover and the lower cover are not firmly coupled when the body is coupled to the body, there is a risk that an accident may occur, such as an explosion due to the high pressure of the pressure medium, but a safety device for this And there is a need for a strong coupling structure.

In addition, the conventional isostatic pressurizing device adopts a method of directly heating a pressure vessel to heat the workpiece. Accordingly, not only takes a long time to heat the workpiece, but also wastes heat loss severely and uniformly heats the workpiece. There is a problem that it is difficult to heat to one temperature.

Other conventional isostatic pressurization devices disclose a technique of circulating a pressure medium by forming a circulation path in an internal vessel for accommodating a workpiece, but heat is released by the pressure vessel and the pressure medium with a low temperature is circulated while the pressure is raised. There is a problem in that the temperature accuracy is deteriorated.

That is, the conventional isostatic pressurization device circulates the pressure medium or heats the pressure vessel so that the workpiece can be heated to a uniform temperature, but the circulation of the pressure medium using the circulation path is not made smoothly and when the pressure vessel is heated There is a problem in that it is difficult to uniformly heat the pressure medium.

Republic of Korea Patent Registration No. 10-0871952 (2008.11.27.)

The present invention is a technique devised to solve the problems according to the above-mentioned prior art, and the conventional hydrostatic pressure device makes it difficult to circulate a pressurized medium for heating or cooling a workpiece inside the inner vessel, and uniformly heats the pressurized medium or It is difficult to cool, and there is a problem that the temperature accuracy is lowered;

As a solution to this, an insertion groove is formed, an external vessel in which a first toothed portion is protruded from the insertion groove, and a second toothed portion corresponding to the first toothed portion is formed to protrude on the outer peripheral surface and is rotationally coupled to the insertion groove A magnet drive coupled to the upper cap and the lower portion of the upper cap and operated in a non-contact manner by magnetic force with an inner vessel inserted into the insertion groove, and a circulation operated by the magnet drive to circulate the pressurized medium supplied to the insertion groove By including the part, the temperature precision of the pressurized medium heated or cooled through the operation of the smooth circulation unit by the magnet drive, that is, the pressurized medium inside the inner vessel can be quickly formed to a uniform temperature, and compressed at a uniform temperature Its main object is to provide through a hydrostatic device equipped with a non-contact agitation conveying system that enables molding to be carried out.

In order to realize the desired object as described above, an insertion groove is formed on the upper surface of the present invention, and the external vessel receiving the pressurized medium from the supply unit to the insertion groove is inserted and coupled to the upper portion of the insertion groove, and the lower portion of the insertion groove The upper cap sealing the upper cap is coupled to the lower part of the upper cap and inserted into the insertion groove, and is installed on the upper part of the inner vessel and the upper cap in which a receiving space for receiving a workpiece is formed therein, and the rotation shaft is the upper cap Installed so as to penetrate through the magnet drive and doedoe installed on the lower surface of the upper cap, it proposes a hydrostatic device equipped with a non-contact stirring transport system, characterized in that it comprises a circulation part installed to be connected to the lower part of the rotation shaft.

In addition, the circulation part of the present invention is installed on the lower surface of the upper cap, the impeller member is installed to be connected to the lower portion of the rotation shaft to suck the pressurized medium, and the impeller member is installed on one side or the other side of the impeller member sucked pressurized medium It characterized in that it is configured to include a discharge pipe for discharging to the lower portion of the insertion groove.

In addition, in the impeller member of the present invention, the upper portion is embedded in the lower surface of the upper cap, the suction hole is formed through the body, and the discharge hole through which the upper part of the discharge pipe is coupled is formed at one side of the suction hole. It is connected to the lower portion of the rotating shaft, characterized in that it is configured to include an impeller installed so as to be positioned above the suction hole of the main body.

In addition, the impeller of the present invention is characterized in that it is configured to include a plurality of blades formed parallel to a horizontal plane and a bent portion formed by bending one end of the blade to be inclined downwardly.

In addition, the inner surface of the inner vessel and the inner surface of the insertion groove of the outer vessel of the present invention is characterized in that it is configured to include a coating layer made of a metal or synthetic resin material with high thermal conductivity.

In addition, the first and second sawtooth portions of the present invention are formed by arranging a plurality of teeth vertically, and the teeth are characterized in that they are formed in a triangular shape in which the thickness decreases in the protruding direction.

In addition, the present invention is characterized in that it comprises a fixing pin member inserted into the space formed in the insertion groove is coupled when the first toothed portion of the outer vessel and the second toothed portion of the upper cap are engaged with each other. do.

In addition, the present invention is installed in the space formed in the insertion groove when the base frame rotatably coupled to the upper portion of the upper cap and the first toothed portion of the outer vessel and the second toothed portion of the upper cap are engaged with each other. Doedoe, it is installed through the base frame, characterized in that it is configured to include a pair of cylinder pins installed to be positioned on both sides of the first toothed portion and the first toothed portion.

In addition, the present invention is a base frame that is rotatably coupled to the upper portion of the upper cap and the rear is installed so as to be rotatable in the horizontal direction on the lower surface of the base frame, and the front of the rod is connected to the upper surface of the upper cap. It is installed on the rotating cylinder and the base frame, characterized in that it is configured to include a limit sensor for detecting the end of the rod of the rotating cylinder.

In addition, the limit sensor unit of the present invention when the rotation cylinder is operated so that the length of the rod becomes longer, a coupling detection sensor for detecting the end of the rod and the end of the rod when the rotation cylinder is operated so that the length of the rod is shortened It is characterized in that it is configured to include a separation detection sensor to detect the.

The hydrostatic pressure device provided with the non-contact stirring transport system according to the present invention presented as described above includes an external vessel in which an insertion groove is formed, a first toothed portion protrudes into the insertion groove, and a first tooth corresponding to the first toothed portion on the outer circumferential surface. An upper cap with two teeth protruding and rotationally coupled to the insertion groove, and a magnet drive operated in a non-contact manner by magnetic force with an inner vessel coupled to a lower portion of the upper cap and inserted into the insertion groove, and the magnet drive. By being configured to include a circulation unit that circulates the pressurized medium supplied to the insertion groove, the temperature accuracy of the pressurized medium heated or cooled through the smooth operation of the circulation unit by the magnet drive, that is, the pressurized medium inside the inner vessel is quickly uniformed Since it can be formed at one temperature, it is possible to obtain the effect that compression molding can be performed at a uniform temperature.

1 is a perspective view showing a hydrostatic pressure device system according to a preferred embodiment of the present invention.
Figure 2 is a perspective view showing a hydrostatic device according to a preferred embodiment of the present invention.
Figure 3 is a perspective view showing a hydrostatic device coupled to the upper cap according to a preferred embodiment of the present invention.
Figure 4 is a front view showing a hydrostatic device coupled to the upper cap according to a preferred embodiment of the present invention.
5 is a cross-sectional view taken along line "AA" of FIG.
6 is a partially enlarged cross-sectional view taken along line "AA" of FIG.
7 is an enlarged view of a portion "B" of FIG.
8 is a perspective view showing a circulation unit according to a preferred embodiment of the present invention.
9 is a plan view showing a hydrostatic pressure device according to a preferred embodiment of the present invention.
10 is a cross-sectional view taken along line "CC" of FIG.
11 is a perspective view from another angle showing a hydrostatic device according to a preferred embodiment of the present invention.
12 is a perspective view from another angle showing a hydrostatic device according to a preferred embodiment of the present invention.
13 is a plan view showing an upper cap and a rotating cylinder according to a preferred embodiment of the present invention.
14 is a partial cross-sectional view in which the outer vessel and the upper cap are combined according to a preferred embodiment of the present invention.
15 is an experimental view showing the results of measuring the stress intensity of the teeth in a state in which the outer vessel and the upper cap are coupled according to a preferred embodiment of the present invention.
16 is a partial plan view showing a state in which the fixing pin member is coupled according to a preferred embodiment of the present invention.
17 is a partial plan view showing a state in which a cylinder pin is coupled according to a preferred embodiment of the present invention.

The present invention relates to a hydrostatic pressure device that is provided with a non-contact stirring transfer system to smoothly circulate a pressurized medium. The outer vessel 100 from which the portion 120 is protruded, and the second toothed portion 210 corresponding to the first toothed portion 120 on the outer circumferential surface are formed to protrude, and the upper portion is rotationally coupled to the insertion groove 110 . It is operated by the inner vessel 300 coupled to the lower portion of the cap 200 and the upper cap 200 and inserted into the insertion groove 110, the magnet drive operated in a non-contact manner by magnetic force, and the magnet drive. By including a circulation unit 500 for circulating the pressurized medium supplied to the insertion groove 110 , the insertion groove 110 , that is, the temperature of the injected pressurized medium supplied to the inside of the inner vessel 300 . It is a technology related to a hydrostatic pressure device (hereinafter referred to as a 'hydrostatic pressure device') equipped with a non-contact stirring and conveying system that minimizes deviation and allows a workpiece to be compression molded at a uniform temperature.

In the configuration for achieving the present invention as described above, the insertion groove 110 is formed on the upper surface, and the external vessel 100 receives the pressurized medium from the supply unit 10 to the insertion groove 110; and the insertion groove The upper cap 200 is inserted and coupled to 110 to seal the lower portion of the insertion groove 110; and the upper cap 200 is coupled to the lower portion of the upper cap 200 and inserted into the insertion groove 110, and the workpiece is inside The inner vessel 300 in which the receiving space 310 accommodated in the is formed; and the magnet drive 400 installed on the upper part of the upper cap 200 so that the rotating shaft 410 passes through the upper cap 200 . ); and a circulation unit 500 installed on the lower surface of the upper cap 200 and connected to the lower portion of the rotation shaft 410 .

In addition, the circulation unit 500 of the present invention is installed on the lower surface of the upper cap 200, the impeller member 510 is installed to be connected to the lower portion of the rotation shaft 410 to suck the pressurized medium; and A discharge pipe 520 installed on one side or the other side of the impeller member 510 to discharge the sucked pressurized medium to the lower portion of the insertion groove 110; characterized in that it is configured to include.

In addition, the impeller member 510 of the present invention is installed with an upper portion buried in the lower surface of the upper cap 200, a suction hole (not shown) is formed through, and an upper portion of the discharge pipe 520 at one side of the suction hole. A main body 512 through which a discharge hole (not shown) to which is coupled is formed; and an impeller 514 connected to a lower portion of the rotation shaft 410 and installed to be positioned above the suction hole of the main body 512; includes; It is characterized in that it is configured.

In addition, the impeller 514 of the present invention includes a plurality of blades 514a formed parallel to the horizontal plane; and a bent portion 514b formed by bending one end of the blade 514a to be inclined downwardly. It is characterized in that it is configured.

In addition, the inner surface of the inner vessel 300 of the present invention and the inner surface of the insertion groove 110 of the outer vessel 100 are a coating layer 20 made of a metal or synthetic resin material with high thermal conductivity; characterized.

In addition, the first toothed portion 120 and the second toothed portion 210 of the present invention are formed in which a plurality of teeth 122 and 212 are vertically arranged, and the teeth 122 and 212 are protruding directions. It is characterized in that it is formed in a triangular shape with a smaller thickness.

In addition, the present invention provides an interspace formed in the insertion groove 110 when the first toothed portion 120 of the outer vessel 100 and the second toothed portion 210 of the upper cap 200 are engaged with each other. It is characterized in that it is configured to include; a fixing pin member (600) that is inserted and coupled to the (112).

In addition, the present invention is a base frame 220 rotatably coupled to the upper portion of the upper cap 200; and the first toothed portion 120 of the outer vessel 100 and the second of the upper cap 200 When the toothed portion 210 is engaged and coupled, it is installed in the interspace 112 formed in the insertion groove 110 , is installed through the base frame 220 , and the first toothed portion 120 and A pair of cylinder pins 700 installed so as to be positioned on both sides of the first toothed portion 120; characterized in that it is configured to include.

In addition, the present invention is a base frame 220 that is rotatably coupled to the upper portion of the upper cap 200; and is installed on the lower surface of the base frame 220 so that the rear is rotatably rotatable in the horizontal direction, and the upper cap a rotating cylinder 230 to which the front of the rod 232 is connected to the upper surface of the 200; And it is installed on the base frame 220, the limit sensor unit 240 for detecting the end of the rod 232 of the rotating cylinder 230; characterized in that it is configured to include.

In addition, the limit sensor unit 240 of the present invention is a coupling detection sensor 242 for detecting the end of the rod 232 when the rotating cylinder 230 is operated so that the length of the rod 232 becomes longer; and and a separation detection sensor 242 for detecting the end of the rod 232 when the rotating cylinder 230 is operated so that the length of the rod 232 is shortened.

Hereinafter, the present invention will be described in detail with reference to FIGS. 1 to 17 showing an embodiment of the present invention.

The outer vessel 100, which is a main component for achieving the present invention, is

An insertion groove 110 is formed on the upper surface, and at least one first toothed part 120 is protruded from the inner circumferential surface of the insertion groove 110 , and the pressurizing medium is fed from the supply part 10 into the insertion groove 110 . As supplied to, the supply part 10 and the lower part are connected by a connecting pipe (not shown) to receive a pressurized medium to the lower part of the insertion groove 110 , and the interior to be described in detail later in the insertion groove 110 . The vessel 300 is inserted, and the upper cap 200, which will be described in detail later, is coupled to the insertion groove 110, so that the insertion groove 110 is sealed in an airtight state.

When the insertion groove 110 is described again, the upper portion of the outer vessel 100 is opened so that the inner vessel 300 and the upper cap 200, which will be described in detail later, are inserted from the upper portion, and the upper cap ( 200), the upper part is sealed.

At least one of the first sawtooth portions 120 is formed to protrude from the inner circumferential surface of the insertion groove 110 , and two or more are formed so that the upper cap 200 , which will be described in detail later, is securely coupled to each other more stably. Preferably, the present invention will be described based on the formation of four first toothed portions 120 .

At this time, the first toothed portion 120 may be formed in the shape of a general screw thread, that is, inclined, or may be formed in a horizontal direction without inclination, that is, in the inner periphery direction of the insertion groove 110 , which is then When the upper cap 200, which will be described in detail, is rotated after being inserted into the insertion groove 110 and coupled thereto, it may be formed by any method, provided that airtightness can be formed by maintaining a firmly coupled state, and in the present invention It will be described on the basis that the length of the first toothed part 120 is formed in the horizontal direction, and protrudes along the inner periphery direction of the insertion groove 110 .

In addition, as at least one of the first toothed portion 120 protrudes from the inner circumferential surface of the insertion groove 110, an inner circumferential surface in which the first toothed portion 120 is not formed is formed, which will be described in detail later. After the upper cap 200 is coupled, an interspace 112 is formed on the inner circumferential surface where the first toothed portion 120 is not formed, and the interspace 112 is a fixing pin member 600 to be described in detail later. Alternatively, the cylinder pin 700 is inserted to prevent rotation of the upper cap 200 , thereby realizing the effect of stably maintaining the coupled state of the upper cap 200 .

The upper cap 200, which is a major component for achieving the present invention, is

As it is inserted into the upper portion of the insertion groove 110 of the external vessel 100 and then rotated and coupled to seal the lower portion of the insertion groove 110 , the lower portion of the insertion groove 110 will be described in detail later. The inner vessel 300 is positioned so that the upper portion of the insertion groove 110 is sealed so that the workpiece can be molded by the pressurizing medium supplied to and filled in the insertion groove 110 so that the lower portion of the insertion groove 110 is closed. Allow confidentiality to be established.

More specifically, in the upper cap 220 of the present invention, at least one second toothed portion 210 corresponding to the first toothed portion 120 is protruded from the outer circumferential surface, and the first toothed portion 120 . As the and second toothed portion 210 are engaged and coupled, the upper portion of the insertion groove 110 is sealed to form an airtight at the lower portion of the upper portion of the groove 110 , and the second toothed portion 210 is the After being positioned on a vertical line in which the first toothed portion 120 is not formed, it is inserted into the insertion groove 110 and rotated by a rotary cylinder 230 to be described in detail later with the first toothed portion 120 and The second toothed portion 210 is engaged and coupled to the outer vessel 100 .

At this time, an inclined step (not shown) is formed on the inner circumferential surface of the insertion groove 110 , and an inclined surface corresponding to the inclined step is formed on the lower outer circumferential surface of the upper cap 200 , so that the upper cap 200 is coupled. As a result, the upper portion of the insertion groove 110 is sealed and airtight is formed at the lower portion, and the inner vessel 300, which will be described in detail later, is inserted into the insertion groove 110 in a state coupled to the lower portion of the upper cap 200 . When they are inserted together, they are located in the lower part of the airtight insertion groove 110 , and the workpiece is molded by the pressurizing medium.

That is, the upper cap 200 is only inserted into the insertion groove 110 so that the upper portion of the insertion groove 110 is sealed and airtight is formed in the lower portion, and is rotated to the first toothed portion 120 . As the second toothed portion 210 is engaged and coupled, it is possible to stably maintain a state in which airtightness is formed in the lower portion of the insertion groove 110 .

The second toothed portion 210 is formed to correspond to the number of the first toothed portion 120 , and is formed to be engaged with the first toothed portion 120 .

As for the upper cap 200 of the present invention, as at least one of the second toothed portions 210 protrude from the outer circumferential surface, the outer circumferential surface in which the second toothed portion 210 is not formed is formed, which, as described above, After the first toothed portion 120 and the second toothed portion 210 are engaged and coupled, an interspace 112 is formed together with the insertion groove 110 .

In connection with the above, the first toothed portion 120 and the second toothed portion 210 are formed by vertically arranging a plurality of teeth 122 and 212, respectively, when the upper cap 200 is rotated. , The teeth 212 of the second teeth 210 are interposed between the teeth 122 of the first teeth 120 and are engaged with each other.

At this time, the teeth 122 and 212 are characterized in that they are formed in a trapezoidal shape in which the thickness is reduced in the protruding direction, which realizes the effect of maintaining a structurally more stable coupled state, that is, an engaged state.

Specifically, the teeth 122 and 212 are formed in a trapezoidal shape in which the thickness decreases in the protruding direction, and the angle between the lower surface and the horizontal plane is 40 to 50°, and the angle between the upper surface and the horizontal plane is 0°. It is characterized in that, when a pressure medium is filled in the sealed lower portion of the insertion groove 110 and pressure is generated, the coupled state can be maintained more stably, and most preferably, it is formed at 45° to make it more stable and can maintain a tightly coupled state.

In addition, the teeth 122 and 212 are characterized in that the distance between the teeth 122 and 212 and the teeth 122 and 212 arranged vertically, that is, the pitch is 55 to 65 mm, which is described above. Together with the angle of the lower surface, it is possible to maintain a more secure and strongly coupled state structurally, and most preferably, it is formed in 60 mm to maintain a more stable and firmly coupled state.

In addition, the teeth 122, 212 are characterized in that the protruding length, that is, the length from the inner circumferential surface of the insertion groove 110 to the distal end, and from the outer circumferential surface to the distal end of the upper cap 200 is 35 to 37 mm, This makes it possible to maintain a structurally more secure and firmly coupled state with the angle and pitch of the lower surface described above, and is most preferably formed of 36 mm to maintain a more stable and firmly coupled state.

Specifically, when the tooth 212 of the second toothed part 210 is described based on the shape, the lower surface is formed to be inclined upward in the protruding direction, that is, toward the outer direction of the upper cap 200, It is characterized in that the upper surface is formed parallel to the horizontal surface, and is formed in a trapezoidal shape to realize the effect of maintaining a structurally more stable and strong bonding state as described above.

At this time, the teeth 122 of the first toothed portion 120 are formed in a shape corresponding to the teeth 212 of the second toothed portion 210 , that is, the teeth of the second toothed portion 210 . (212) and the same shape, but the upper surface and the lower surface is formed in an inverted shape.

On the other hand, when the upper cap 200 of the present invention is inserted into the insertion groove 110 of the outer vessel 100 as shown in FIG. 6 , the air or pressurized medium inside the insertion groove 110 is It may be configured to include a vent (not shown) that can be discharged to the outside.

As shown in FIG. 6 , the vent portion is elastically supported upward by an elastic member (spring) so that it can be more firmly closed when pressure is generated by air or a pressurized medium inside the insertion groove 110 . It is configured to include a check valve (not shown) which becomes a check valve (not shown) and a discharge passage (not shown) formed in the lateral direction of the upper cap 200 in communication with the upper part of the check valve, and the upper cap 200 is installed on the upper part, and the check It may be configured to further include a control cylinder (not shown) connected to the valve to open or close the check valve.

At this time, the external vessel 100 has a discharge passage (not shown) corresponding to the discharge passage is formed so that the air or pressurized medium discharged through the discharge passage is discharged to the outside and removed.

In connection with the above, the hydrostatic pressure device of the present invention is installed so that the rear side is rotatable in the horizontal direction on the lower surface of the base frame 220 and the base frame 220 rotatably coupled to the upper portion of the upper cap 200 . The end of the rod 232 of the rotating cylinder 230 is installed in the rotating cylinder 230 and the base frame 220 to which the front of the rod 232 is connected to the upper surface of the upper cap 200 . It is characterized in that it is configured to include a limit sensor unit 240 to detect.

The base frame 220 is rotatably coupled to the upper portion of the upper cap 200, that is, the base frame 220 is rotatably coupled to the lower portion of the upper cap 200, and the When the upper cap 200 is rotated by the rotating cylinder 230, the upper part of the upper cap 200 is stably supported.

At this time, the upper portion of the upper cap 200 is coupled through the base frame 220, it is preferable to be coupled to be stably rotated by a bearing (not shown).

The rotation cylinder 230 rotates the upper cap 200 so that the first toothed portion 120 and the second toothed portion 210 described above are engaged, so that the upper cap 200 is the outer vessel ( 100), that is, to be coupled to the insertion groove 110 .

At this time, the rear of the rotating cylinder 230 is fixedly coupled to the lower surface of the base frame 220 , and even if it is coupled to be rotatable in the horizontal direction, the front of the rod 232 is the upper surface of the upper cap 200 . It is connected to one side or the other side so as to be rotatably rotatable in the horizontal direction, and the upper cap 200 is rotated by the operation of the rod 232 .

In addition, the rotating cylinder 230 is configured to include a rear bracket (not shown) that is fixedly coupled to the lower surface of the base frame 220, and the rear is rotatably coupled to the rear bracket in a horizontal direction.

In addition, the rotating cylinder 230 is rotatably coupled to the front side of the rod 232 in the horizontal direction, and a front bracket to which the front side is coupled to one or the other side of the upper surface of the upper cap 200 (not shown) is comprised of

That is, the rotating cylinder 230 is operated by a control unit or a control panel (hereinafter, collectively referred to as a 'control unit') for controlling the hydrostatic pressure device of the present invention, and the upper cap 200 is moved by the rod 232 . By rotating, the second toothed portion 210 of the upper cap 200 inserted into the insertion groove 110 of the outer vessel 100 is stably coupled to the first toothed portion 120 .

At this time, the rotating cylinder 230 may be configured to include a motion detection sensor (not shown) that is installed inside and senses the length of the rod 232 withdrawn and pulled out, the motion detection sensor is the sensed rod ( 232) to the control unit so that the control unit can calculate the rotated angle of the upper cap 200 according to the operation of the rotating cylinder 230, so that the upper cap 200 is attached to the outer vessel 100. It realizes the effect of confirming that it is firmly coupled.

The limit sensor unit 240 is installed on the base frame 220 to detect the end of the rod 232 of the rotary cylinder 230, so that the rotation of the upper cap 200 overlaps with the motion sensor. It is possible to check whether it is made by a precisely preset angle, and accordingly, the effect of confirming whether the coupling of the upper cap 200 and the outer vessel 100 is firmly and precisely made is realized.

In addition, since the rear of the front bracket is actually coupled to the front of the rod 232, the limit sensor unit 240 is in contact with the rear of the front bracket to detect the operation of the rotary cylinder 230. .

Specifically, when the rotation cylinder 230 is operated so that the length of the rod 232 becomes longer, the limit sensor unit 240 is the second toothed portion 210 of the upper cap 200 is the first toothed portion. When the rotating cylinder 230 rotates the upper cap 200 to engage 120, a coupling detection sensor 242 for detecting the end of the rod 232, that is, the rear of the front bracket, and the rod 232 ) when the rotary cylinder 230 is operated to shorten the length, that is, the second toothed part 210 of the upper cap 200 is separated from the first toothed part 120. When the cap 200 is rotated, it is configured to include a separation detection sensor 242 for detecting the end of the rod 232 , that is, the rear of the front bracket.

That is, the limit sensor unit 240 detects the operation of the rotary cylinder 230 through the coupling detection sensor 242 and the separation detection sensor 242 as described above, so that the upper cap 200 is the outer vessel ( 100) to confirm that it is combined or separated to realize the effect of more safely molding.

In addition, the hydrostatic pressure device of the present invention is installed on the base frame 220 in the forward direction of the upper cap 200 , that is, the second toothed portion 210 is rotated to engage the first toothed portion 120 or the reverse direction. That is, after the second toothed part 210 is rotated in the rotational direction to be separated from the first toothed part 120, including a pair of anti-rotation cylinders 800 for preventing the rotation of the upper cap 200 can be configured.

Specifically, the anti-rotation cylinder 800 is installed on the upper portion of the base frame 220, a rod (not shown) is installed through the base frame 220 in the lower direction, and the upper cap 200 is By including a fixing groove (not shown) formed so that the rod of the anti-rotation cylinder 800 can be drawn in and out after rotating in the forward or reverse direction, as described above, the upper cap by the anti-rotation cylinder 800 After the rotation of 200, the rotation of the upper cap 200 is limited, so that more improved stability can be obtained.

In relation to the above, the hydrostatic pressure device of the present invention is configured to include a lifting cylinder 222 installed on any one of the lower side of one side or the lower side of the base frame 220, and the lifting cylinder 222 is provided to the control unit. By controlling the upper cap 200 to elevate, the upper cap 200 is stably inserted into or separated from the insertion groove 110 of the outer vessel 100 . At this time, the lifting cylinder 222 is installed in the lower front or rear lower portion of the base frame 220 , that is, in the lower portion of the base frame 220 , and at least one is installed so as to be located outside the external vessel 100 . It will be obvious that it can be, and the number is not limited thereto.

On the other hand, as described above, in the hydrostatic device of the present invention, when the first toothed portion 120 of the outer vessel 100 and the second toothed portion 210 of the upper cap 200 are engaged and coupled, the insertion It is characterized in that it comprises a fixing pin member 600 inserted into the groove 110, that is, the interspace 112 formed between the outer vessel 100 and the upper cap 200, and coupled thereto.

In other words, the fixing pin member 600 is a case in which the first toothed portion 120 of the outer vessel 100 and the second toothed portion 210 of the upper cap 200 are engaged and coupled, that is, the upper cap ( When the 200) is rotated after being inserted into the insertion groove 110 and coupled, the first toothed portion 120 and the second toothed portion 210 are inserted into and coupled to the insertion groove 110 where they are not located.

The fixing pin member 600 is inserted into the interspace 112 to limit the rotation of the upper cap 200 coupled to the outer vessel 100 , so that the upper cap 200 is moved to the outer vessel 100 . ) to ensure more improved stability by firmly maintaining the bonded state.

At this time, when the fixing pin member 600 is coupled to the interspace 112 , it may be difficult to couple by the base frame 220 , so that the base frame 220 corresponds to the interspace 112 . A through hole (not shown) that is formed through the hole is formed, and after the upper cap 200 is coupled to the outer vessel 100 through the through hole, the fixing pin member 600 is smoothly inserted into the interspace 112 . It is preferable to insert

In addition, in the hydrostatic device of the present invention, instead of the fixing pin member 600 , the first toothed portion 120 of the outer vessel 100 and the second toothed portion 210 of the upper cap 200 are engaged and coupled. In this case, it is installed in the insertion groove 110 , that is, in the space 112 formed between the outer vessel 100 and the upper cap 200 , is installed through the base frame 220 , and the first It is characterized in that it is configured to include at least one cylinder pin 700 that is installed to be located on both sides of the toothed portion 120 or the second toothed portion 210 .

In other words, the cylinder pin 700 is a case in which the first toothed portion 120 of the outer vessel 100 and the second toothed portion 210 of the upper cap 200 are engaged and coupled, that is, the upper cap 200 ) is installed through the base frame 220 when it is rotated and coupled after being inserted into the insertion groove 110 , and is installed on both sides of the first toothed portion 120 or the second toothed portion 210 .

The cylinder pin 700 is installed by being inserted into the interspace 112 , and installed on both sides of the first toothed part 120 or the second toothed part 210 to rotate the second toothed part 210 . By limiting what is done, it is possible to secure more improved stability by allowing the upper cap 200 to firmly maintain a state coupled to the outer vessel 100 .

At this time, when the cylinder pin 700 is coupled to the interspace 112 , it may be difficult to couple by the base frame 220 , and it may be difficult to be fixed to the interspace 112 , so the base frame Corresponding to the interspace 112 in 220, a through hole (not shown) through which the cylinder pin 700 is inserted and formed to correspond to the installed position is formed, and the upper cap ( After the 200) is coupled to the outer vessel 100, it is preferable to smoothly insert the cylinder pin 700 into the interspace 112 and then be fixed.

In addition, it is installed on the upper portion of the base frame 220, it may be configured to further include a fixed cylinder (not shown) for elevating the cylinder pin 700, the fixed cylinder is the upper cap 200 is external After being coupled to the insertion groove 110 of the vessel 100, it is controlled by the control unit to realize the effect of maintaining the cylinder pin 700 stably and firmly installed.

The inner vessel 300, which is a main component for achieving the present invention, is

It is coupled to the lower portion of the upper cap 200 and is inserted together when the upper cap 200 is inserted into the insertion groove 110 of the outer vessel 100 and is inserted into the lower portion of the insertion groove 110, A accommodating space 310 in which a workpiece (not shown) is accommodated is formed, and when the upper cap 200 is inserted into the insertion groove 110 of the outer vessel 100 and then coupled, the insertion groove 110 ), the workpiece is molded by the pressurized medium supplied to the inside.

At this time, the inner vessel 300 of the present invention is provided with an openable and openable door (not shown) so that the workpiece can be seated in the receiving space 310 , and the pressurized medium is heated or cooled inside the receiving space 310 . A heating pipe 320 and a cooling pipe 330 that can It is connected to heat the pressurized medium by the heater or to cool the pressurized medium by circulation of cooling water.

In addition, the workpiece is molded through a pressurized medium filled in the lower portion of the airtight insertion groove 110, and in particular, as it is accommodated in the receiving space 310 of the inner vessel 300, mainly the It is molded by the temperature and pressure of the pressurized medium filled in the receiving space 310 .

The magnet drive 400, which is a main component for achieving the present invention, is

It is installed on the upper part of the upper cap 200, and the rotating shaft 410 is installed to pass through the upper cap 200. A method of rotating the inner rotating magnet located inside the outer magnet using magnetic force. , has a structure that can rotate an object (up to an object coupled with an inner rotor magnet) located inside the outer magnet in a non-contact manner by magnetic force, and the inner rotor magnet and the rotation shaft 410 are coupled, and then The rotation shaft 410 is connected to the impeller 514 of the circulation unit 500 to be described in detail to rotate the impeller 514 .

As such, the magnet drive of the present invention is a technology that has been conventionally used in various industrial fields, and a detailed description thereof will be omitted, and as the impeller 514 of the circulation unit 500 to be described in detail is smoothly rotated, the inner vessel (300) so that the circulation of the internal pressurized medium can be made effectively.

In addition, the rotation shaft 410 is airtight formed with the upper cap 200 so that the pressurized medium absorbed by the impeller 514, which will be described in detail later, does not leak, is rotatably coupled.

In more detail, the upper cap 200 is formed on the lower surface, and is configured to include a bushing groove (not shown) formed so that the lower end of the rotating shaft 410 is positioned, and the rotating shaft 410 is the lower It is installed on the outer periphery and is configured to include a bushing 412 installed in the bushing groove, and the bushing 412 serves as a bearing to smoothly rotate the rotation shaft 410 and at the same time as the bushing groove It realizes the effect of preventing the pressurized medium from leaking by the rotating shaft 410 by sealing the upper part of the .

The circulation unit 500, which is a main component for achieving the present invention, is

It is installed on the lower surface of the upper cap 200, and is installed to be connected to the lower part of the rotation shaft 410. The impeller 514, which will be described in detail later by the magnet drive 400 described above, is rotated inside By allowing the pressurized medium filled in the vessel 300 to circulate, the temperature of the cooled or heated pressurized medium can be made uniform so that the molding of the workpiece can be performed at a uniform temperature.

Specifically, the circulation unit 500 of the present invention is installed on the lower surface of the upper cap 200, the impeller member 510 installed to be connected to the lower portion of the rotation shaft 410 to suck the pressurized medium, and the It is installed on one side or the other side of the impeller member 510 is configured to include a discharge pipe 520 for discharging the sucked pressurized medium to the lower portion of the insertion groove (110).

In addition, the impeller member 510 is installed on the lower surface of the upper cap 200, a suction hole (not shown) is formed through, and the upper portion of the discharge pipe 520 is coupled to one side of the suction hole. It is configured to include a main body 512 through which a hole (not shown) is formed, and an impeller 514 connected to a lower portion of the rotation shaft 410 and installed to be positioned above the suction hole of the main body 512 .

At this time, the coupling between the impeller 514 and the rotating shaft 410 is made through a coupling bolt 414 that passes through the center of the impeller 514 and is screwed to the lower surface of the rotating shaft 410, the coupling bolt Reference numeral 414 is preferably coupled to the rotation shaft 410 through screwing in the opposite direction to the rotation direction of the rotation shaft 410 to prevent loosening by the rotation of the rotation shaft 410 .

In addition, the upper cap 200 is configured to include a suction groove 250 formed on the lower surface, and the impeller 514 is installed in the suction groove 250 to be smoothly operated by the magnet drive 400 . It is rotated to suck the pressurized medium, and it will be apparent that the above-described bushing groove is formed on the suction groove 250 .

That is, in the circulation unit 500 of the present invention, when the impeller 514 is rotated by the operation of the magnet drive 400, the pressurized medium with a relatively high temperature located at the top of the pressurized media that is heated or cooled is the impeller 514. ) through the suction hole of the main body 512 and then moved along the discharge pipe 520 installed in the discharge hole to move to the lower part of the insertion groove 110 , that is, to the lower part of the receiving space 310 so that it can be circulated. , so that the temperature of the pressurized medium can be uniformly made more effectively.

In other words, in the circulation unit 500 of the present invention, since the main body is installed on the lower surface of the upper cap 200 , the pressurized medium located on the upper part of the sealed insertion groove 110 , that is, the upper part of the receiving space 310 . By discharging the suctioned pressurized medium to the lower part of the sealed insertion groove 110, that is, to the lower part of the receiving space 310 after suction, the pressurized medium is circulated so that the temperature of the heated or cooled pressurized medium is more efficiently uniform. You can get the effect that makes it happen.

At this time, the impeller 514 is formed radially, a plurality of blades 514a formed in parallel with a horizontal plane, and one end of the blade 514a is bent downwardly and is formed to be inclined in the rotational direction. It is characterized in that it is configured to include a bent portion 514b, and through the bent portion 514b, not only can the effect of more smoothly being sucked in the pressurized medium be obtained, but also the pressurized medium vortexed after being sucked in the direction of the discharge hole By allowing it to move, the effect of smoothly moving the pressurized medium sucked through the discharge pipe 520 is realized.

In addition, the main body 512 is installed on the upper surface, and is installed between the impeller 514 and the discharge hole and includes a guide block 512a to guide the sucked pressurized medium in the direction of the discharge hole. The guide block 512a is formed on the other side of the suction groove 250 formed on the lower surface of the upper cap 200 , that is, the discharge hole is formed so that the width of the suction groove 250 becomes narrower toward the side of the suction groove 250 . By doing so, by further increasing the flow rate of the sucked pressurized medium, the pressurized medium can be more smoothly discharged through the discharge hole, that is, the discharge pipe 520, thereby realizing the effect of making the circulation of the pressurized medium more efficient. do it

In addition, the blade 514a is formed at the other end, is formed to be positioned at the outer end of the impeller 514, and is configured to include a wedge portion 514a-1 protruding in a direction opposite to the rotation direction, the wedge The portion 514a-1 not only increases the flow rate of the pressurized medium sucked by the bent portion 514b so that suction can be performed smoothly, but also prevents the sucked pressurized medium from flowing backward in the downward direction, It realizes the effect of allowing the pressurized medium to be smoothly moved and discharged in the direction of the discharge hole, that is, the discharge pipe.

On the other hand, the inner surface of the inner vessel 300 and the inner surface of the insertion groove 110 of the outer vessel 100 is characterized in that it comprises a coating layer 20 made of a metal or synthetic resin material with high thermal conductivity, As the metal or synthetic resin material forming the coating layer 20, any material with high thermal conductivity may be used together with the adhesive component for coating, so a detailed description thereof will be omitted.

The coating layer 20 is coated on the inner surface of the inner surface of the inner vessel 300 and the inner surface of the insertion groove 110 of the outer vessel 100 so that the temperature precision of the pressurized medium heated or cooled, that is, the pressurized medium is at a uniform temperature By making it possible to form a, it realizes the effect of making more precise molding together with the circulation unit 500 .

As a result, the hydrostatic device of the present invention can smoothly circulate the heated or cooled pressurized medium through the non-contact magnet drive 400 and the circulation unit 500 , and in particular, the temperature relative to the pressurized medium located below. By circulating the pressurized medium located in the upper part of the upper part to the lower part, the temperature precision of the pressurized media, that is, the temperature is uniformly made, so that a more improved molding effect can be obtained.

The above has been described with reference to a preferred embodiment of the present invention, and is not limited to the above embodiment, and a person of ordinary skill in the art through the above embodiment does not deviate from the gist of the present invention It can be implemented with various changes in

10: supply unit 20: coating layer
100: outer vessel 110: insertion groove
112: interspace 120: first toothed part
122, 212: tooth 200: upper cap
210: second toothed part 220: base frame
230: rotating cylinder 232: rod
240: limit sensor unit 242: combination detection sensor
244: separation detection sensor 250: suction groove
300: inner vessel 310: accommodation space
320: heating pipe 330: cooling pipe
400: magnet drive 410: rotation shaft
412: bushing 414: bolt
500: circulation part 510: impeller member
512: body 512a: guide block
514: impeller 514a: blade
514a-1: wedge 514b: bend
520: discharge pipe 600: fixing pin member
700: cylinder pin

Claims (10)

An external vessel 100 having an insertion groove 110 formed on the upper surface and receiving a pressurized medium from the supply unit 10 to the insertion groove 110; and
The upper cap 200 is inserted into the insertion groove 110 to seal the lower portion of the insertion groove 110; and
The inner vessel 300 is coupled to the lower portion of the upper cap 200 and inserted into the insertion groove 110, the receiving space 310 in which the workpiece is accommodated is formed; and
a magnet drive 400 installed on the upper part of the upper cap 200 , the rotating shaft 410 passing through the upper cap 200 ; and
It is installed on the lower surface of the upper cap 200, the circulation part 500 is installed to be connected to the lower portion of the rotation shaft 410; is configured to include,
The circulation unit 500 is
Doedoe installed on the lower surface of the upper cap 200, the impeller member 510 installed to be connected to the lower portion of the rotation shaft 410 to suck the pressurized medium; and
Discharge pipe 520 installed on one side or the other side of the impeller member 510 to discharge the sucked pressurized medium to the lower portion of the insertion groove 110; hydrostatic device.
delete According to claim 1,
The impeller member 510 is
The main body 512 installed on the lower surface of the upper cap 200, the suction hole is formed through, and the discharge hole through which the upper part of the discharge pipe 520 is coupled to one side of the suction hole is formed through; and
Impeller (514) connected to the lower portion of the rotation shaft (410) and installed to be positioned above the suction hole of the main body (512); Hydrostatic pressure device provided with a non-contact stirring transport system, characterized in that it comprises a.
4. The method of claim 3,
The impeller 514 is
A plurality of blades (514a) formed parallel to the horizontal plane; and
A hydrostatic pressure device with a non-contact stirring transport system, characterized in that it includes; a bent portion (514b) that is bent downwardly at one end of the blade (514a), the bent portion (514b) is formed to be inclined in the rotational direction.
According to claim 1,
The inner surface of the inner vessel 300 and the inner surface of the insertion groove 110 of the outer vessel 100 are
A hydrostatic pressure device with a non-contact stirring transport system, characterized in that it comprises; a coating layer 20 made of a metal or synthetic resin material with high thermal conductivity.
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