KR102305000B1 - Vertical Downward Hydraulic Press - Google Patents

Abstract

Disclosed is a vertically downward hydraulic compressor. According to an embodiment of the present invention, the vertically downward hydraulic compressor includes: a lower V block placed on the surface of the ground for installation or in an upper part of a facility and having a longitudinal section V-shaped groove formed in an upper center part to place a lower part of a master die therein, and having guide bars mounted on both sides to be extended upward by a predetermined height; an upper V block mounted in an upper part of the lower V block to change a position in a vertical direction along the guide bars, having a longitudinal section V-shaped groove formed in a lower center part to place an upper part of the master die therein, and having fastening structures formed on both sides to be fastened with the guide bars; a head block mounted in an upper part of the guide bars to fasten the both guide bars in an integrated structure, and having a hydraulic cylinder mounted on a lower side to change a vertical position of the upper V block; and the master die placed on the lower V-shaped groove and the upper V-shaped groove at the same time, and compressing an outer circumference surface of an object to be compressed in eight directions spaced apart from each other by a predetermined angle in accordance with a downward operation of the upper V block. According to the present invention, the vertically downward hydraulic compressor, which is constituted to maximize a compression area and stably fix an object to be compressed, can be provided.

Description

Vertical Downward Hydraulic Press

The present invention relates to a vertical downward hydraulic press, and more particularly, to a vertical downward hydraulic press including a configuration capable of maximizing a pressing area and stably fixing an object to be pressed.

In general, large and small bearings, shafts, and pulleys are often used in mechanical devices, and since the fitting tolerance of bearings, shafts, and pulleys for the coupling hole is not large, auxiliary tools such as a hammer are used to disassemble and combine them for maintenance. When working with artificial force through the coupling hole, disassembly and coupling becomes very difficult due to frictional force with the coupling hole, and there is a high risk of damage to their parts or coupling hole during the disassembly and coupling process.

Accordingly, various types of attachment and detachment aids have been proposed, including those made up of a number of fixed rods and lifting rods, and these attachment and detachment aids use a much smaller force compared to when the operator applies direct force to press or pull the rotating support shaft by using a bearing or pulley. Although it is possible to separate or combine them, it still takes a lot of force, and the work becomes extremely cumbersome, and there are problems such as a high risk of damage to the work object in the process of work.

In order to solve this problem, a press for auto parts maintenance in the form of installing a pressure tool on the working rod of a hydraulic cylinder has been proposed, but it is difficult to adjust the height of the conventional press for machine parts processing depending on the size or length of the object to be processed. There was a problem that it could not be used smoothly if the maintenance object was usually large or long.

In order to solve this problem, as shown in Fig. 1, a lower plate 10, a vertical bar 20, an intermediate plate 30, an upper plate 40, a hydraulic cylinder 50, a circular support member of a specific structure ( 60), a press for machining machinery including a pressure adapter 70 and a component accommodating case 100 has been developed.

However, the press shown in FIG. 1 has a structure that can compress the object to be compressed only in the vertical direction by pressing only downward, and thus cannot implement a uniform pressing force along the outer circumferential surface of the cylindrical object to be compressed.

That is, in the case of the press according to the prior art, the operation of pressing the hydraulic hose and the fitting cannot be performed. Furthermore, the press according to the prior art cannot effectively process a compression object having a circular cross-section, such as a wire rope, a round pipe, a square pipe, and a high-pressure water hose.

Therefore, there is a need for a technique capable of solving the above-mentioned problems according to the prior art.

Korean Patent Publication No. 10-0256084 (Registration Date: February 18, 2000)

It is an object of the present invention to provide a vertical downward hydraulic press comprising a configuration capable of maximizing a pressing area and stably fixing an object to be pressed.

The vertical downward hydraulic press according to one aspect of the present invention for achieving this object is seated on the ground or the upper part of the facility to be installed, and a V-shaped groove is formed on the longitudinal section in which the lower part of the master die can be seated in the upper central part, , A lower V block equipped with a guide bar extending upward by a predetermined height on both sides; It is mounted on the upper part of the lower V block so as to be able to change its position in the vertical direction along the guide bar, and a V-shaped groove is formed in the lower central part in which the upper part of the master die can be seated, and a binding structure for binding with the guide bar is formed on both sides. Formed upper V block; a head block mounted on the upper end of the guide bar, binding both guide bars to an integrated structure, and having a hydraulic cylinder mounted on the lower surface to change the vertical position of the upper V block; and a master die seated in the lower V-shaped groove and the upper V-shaped groove at the same time and configured to press the outer peripheral surface of the object to be compressed in 8 directions spaced apart by a predetermined angle according to the downward driving of the upper V block; have.

In one embodiment of the present invention, the lower V block, the upper central portion while longitudinally V-shaped groove formed block body portion; and a sliding rail portion of a plate-shaped structure that is mounted on both inclined surfaces of the V-shaped groove and forms a rail structure so that the lower surface of the master die can change the sliding position along the inclined surface.

In one embodiment of the present invention, the lower V block, is mounted on the inside of the block body portion, the groove interval changing portion for changing the position of the sliding rail portion toward the central portion; may be configured to include.

In this case, the groove interval changing part, the V-shaped groove of the block body part is recessed by a predetermined depth in both sides from both sides of the inclined surface screw binding sphere; a screw that is rotatably mounted on the screw coupling hole and changes the lateral position of the rail mounting part by a rotation operation; a rotation handle part mounted on the other end of the screw, exposed to the outside of one side of the block body part, and rotating the screw; and a rail mounting part mounted on one end of the screw, mounted with a sliding rail part on one side, and changed in a lateral position by a rotation operation of the screw.

In one embodiment of the present invention, the upper V block, the block body portion having a V-shaped groove longitudinally in the lower central portion; and a sliding rail portion of a plate-shaped structure that is mounted on both inclined surfaces of the V-shaped groove and forms a rail structure so that the upper surface of the master die can change the sliding position along the inclined surface.

In one embodiment of the present invention, the upper V block, is mounted on the inside of the block body portion, the groove interval changing portion for changing the position of the sliding rail portion toward the central portion; may be configured to include.

In this case, the groove interval changing part, the V-shaped groove of the block body part is recessed by a predetermined depth in both sides from both sides of the inclined surface screw binding sphere; a screw that is rotatably mounted on the screw coupling hole and changes the lateral position of the rail mounting part by a rotation operation; a rotation handle part mounted on the other end of the screw, exposed to the outside of one side of the block body part, and rotating the screw; and a rail mounting part mounted on one end of the screw, mounted with a sliding rail part on one side, and changed in a lateral position by a rotation operation of the screw.

In one embodiment of the present invention, one hydraulic cylinder mounted on the lower surface of the head block may be mounted on the center of the lower surface of the head block, or a plurality of hydraulic cylinders mounted on the lower surface of the head block may be mounted at regular intervals on the lower surface of the head block. .

In one embodiment of the present invention, the guide bar, the lower V block and the head block form a single U-shaped frame structure on the front side, and a rail structure is formed on the inner surface of the guide bar in the vertical direction, and the upper portion The binding structure formed on both sides of the V block is seated on the rail structure of the guide bar and can be moved vertically by sliding.

In one embodiment of the present invention, the master die is a structure separated into a plurality of pieces spaced apart by a certain angle along the outer circumferential surface of the object to be pressed, and the plurality of pieces are separated into a plurality of pieces according to a change in the lower position of the upper V block. By converging in the central direction, the outer peripheral surface of the object to be pressed can be pressed.

In one embodiment of the present invention, the plurality of pieces of the master die are bound to each other in a sliding rail structure, and each side of the plurality of pieces of the master die is bound to each other by an elastic member, and the upper V By the elastic restoring force of the elastic member according to the change of the upper position of the block, a plurality of pieces are spaced apart at a predetermined interval, and thus may be away from the outer circumferential surface of the object to be compressed.

In one embodiment of the present invention, the master die is seated in the center of the V-shaped groove of the lower V block, and an inclined structure corresponding to the V-shaped groove is formed on both sides of the lower V block, and a predetermined height upward in the upper center. a lower master die in which a pressing protrusion having a curved surface structure corresponding to a portion of the outer circumferential surface of the pressing object is formed, and sliding rails are formed on both sides of the pressing protrusion; Seated on both sides of the V-shaped groove of the lower V block, and at the same time seated on both sides of the V-shaped groove of the upper V block, an inclined structure corresponding to the V-shaped groove of the upper V block is formed on the upper surface, and the lower surface is formed with an inclined surface structure corresponding to the V-shaped groove of the lower V block, and a pressing protrusion having a curved surface structure corresponding to a partial surface of the outer peripheral surface of the pressing object is formed by protruding by a predetermined length in the direction in which the pressing object is arranged in the center of the side, , A side master die having sliding rails formed on both sides of the pressing protrusion; It is seated on the sliding rail of the lower master die and the sliding rail of the side master die at the same time, an elastic member binding to the lower master die is mounted on one side, and an elastic member binding to the side master die is mounted on the other side. a lower auxiliary master die protruding by a predetermined length in the arrangement direction to have a curved structure corresponding to a partial surface of the outer peripheral surface of the object to be pressed; It is seated in the center of the V-shaped groove of the upper V block, an inclined structure corresponding to the V-shaped groove is formed on both sides, and a curved surface structure corresponding to a partial surface of the outer peripheral surface of the object to be pressed by protruding downward by a predetermined height in the lower center. an upper master die having a pressing protrusion formed thereon and sliding rails formed on both sides of the pressing protrusion; and an elastic member that is seated at the same time on the sliding rail of the upper master die and the sliding rail of the side master die, an elastic member binding to the upper master die is mounted on one side, and an elastic member binding to the side master die is mounted on the other side, and the object to be pressed An upper auxiliary master die protruding by a predetermined length in the arrangement direction and having a curved structure corresponding to a partial surface of the outer circumferential surface of the object to be pressed; may include a configuration.

In one embodiment of the present invention, the upper master die may be mounted by a binding member that can be disassembled and assembled in the V-shaped groove of the upper V block.

In one embodiment of the present invention, the curved structure may be a configuration including a plurality of bent structures.

In an embodiment of the present invention, a pressure detection unit mounted on the master die, detecting the magnitude of the pressure applied from the outer peripheral surface of the compression object in real time and transmitting it to the control unit; a control unit for controlling the operation of the hydraulic cylinder based on the data detected by the pressure detection unit; And built in the control unit, in conjunction with the user's smart device through wireless communication, provides the operator with the operating state information of the vertical top-down hydraulic press transmitted from the control unit in real time, and receives a control signal from the operator's smart device to the control unit It may be configured to further include; a wireless communication module to transmit to.

As described above, according to the vertical downward hydraulic press of the present invention, by providing a lower V block, an upper V block, a hydraulic cylinder, a head block, and a master die of a specific structure, the pressing area can be maximized and the compression object can be stably pressed It is possible to provide a vertical downward hydraulic press comprising a configuration that can be fixed to the

In addition, according to the vertical downward hydraulic press of the present invention, one or more hydraulic cylinders can be mounted, and a U-shaped frame structure can be formed, so that the vertical downward hydraulic press can be configured in various shapes and structures, so that the object to be pressed It is possible to provide a vertical downward hydraulic press with an optimized structure in consideration of the range of compression pressure and the installation environment.

In addition, according to the vertical downward hydraulic press of the present invention, by having a groove interval changing unit capable of changing the interval of the V-shaped groove formed in the upper V block and the lower V block, the initial pressurization start position can be changed according to the intention of the operator, and , it is possible to additionally perform compression by driving the groove spacing changer during the compression process, thereby providing a vertical downward hydraulic compression machine that can significantly increase the range of compression.

In addition, according to the vertical downward hydraulic press of the present invention, by having a master die including a lower master die, a side master die, a lower auxiliary master die, an upper master die, an upper auxiliary master die, a sliding rail and an elastic member of a specific structure, , the pressing force by changing the lower position of the upper V block can be evenly distributed along the outer peripheral surface of the compression object and pressurized, so that the pressing force applied evenly along the entire outer peripheral surface, rather than using the unidirectional pressing force according to the prior art, is used to compress the object. can be pressed, providing a vertical downward hydraulic press that can ensure the quality of the compression result.

1 is a perspective view showing a press according to the prior art.
2 is a front view showing a vertical downward hydraulic press according to an embodiment of the present invention.
3 is a front view showing a vertical downward hydraulic press according to another embodiment of the present invention.
FIG. 4 is a partially enlarged view showing the binding state of the guide bar and the upper V block of FIG. 3 .
5 is a front view showing a master die according to an embodiment of the present invention.
6 is a front view showing a groove interval changing unit according to another embodiment of the present invention.
7 is a front view showing only the lower master die and the lower auxiliary master die of the master die according to an embodiment of the present invention.
8 is a schematic diagram showing a state of easily monitoring and controlling the vertical downward hydraulic press according to another embodiment of the present invention using a wireless communication module.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. Prior to this, the terms or words used in the present specification and claims should not be construed as being limited to conventional or dictionary meanings, but should be interpreted as meanings and concepts consistent with the technical spirit of the present invention.

Throughout this specification, when a member is said to be “on” another member, this includes not only a case in which a member is in contact with another member but also a case in which another member is present between the two members. Throughout this specification, when a part "includes" a certain component, it means that other components may be further included rather than excluding other components unless otherwise stated.

2 is a front view showing a vertical downward hydraulic press according to an embodiment of the present invention is shown.

Referring to Figure 2, the vertical downward hydraulic press 100 according to this embodiment, the lower V block 110, the upper V block 120, the hydraulic cylinder 140, the head block 130 and the master of a specific structure. By providing the die 150, it is possible to maximize the pressing area and to provide a vertical downward hydraulic press including a configuration that can stably fix the compression object.

Hereinafter, with reference to the drawings, each configuration constituting the vertical downward hydraulic press 100 according to the present embodiment will be described in detail.

3 is a front view showing a vertical downward hydraulic press according to another embodiment of the present invention is shown, FIG. 4 is a partially enlarged view showing the coupling state of the guide bar and upper V block of FIG. In addition, Figure 5 is a front view showing the master die according to an embodiment of the present invention is shown.

Referring to these drawings together with FIG. 2 , the lower V block 110 according to this embodiment is seated on the ground or the upper part of the facility to be installed, and the lower end of the master die 150 can be seated on the upper central part. A planar V-shaped groove 161 is formed, and guide bars 111 extending upward by a predetermined height may be mounted on both sides.

The upper V block 120 is a configuration that is mounted on the upper portion of the lower V block 110 so as to be positionally changeable in the vertical direction along the guide bar 111, and the upper portion of the master die 150 can be seated in the lower central portion. A V-shaped groove 161 is formed on the longitudinal cross-section, and the binding structure 121 for binding to the guide bar 111 may be formed on both sides.

The head block 130 is a configuration mounted on the upper end of the guide bar 111 , and binds the guide bars 111 on both sides in an integrated structure, and hydraulic pressure for changing the vertical position of the upper V block 120 on the lower surface. A cylinder 140 may be mounted.

In some cases, one hydraulic cylinder 140 mounted on the lower surface of the head block 130 is mounted on the center of the lower surface of the head block 130 or, as shown in FIG. 3 , of the head block 130 . A plurality of spaced apart from the lower surface may be mounted.

In addition, the master die 150 is configured to be seated in the lower V-shaped groove 161 and the upper V-shaped groove 161 at the same time. It may be a structure that presses in 8 directions spaced apart.

In some cases, as shown in FIG. 3 , the guide bar 111 , the lower V block 110 and the head block 130 may form a single U-shaped frame structure on the front. At this time, as shown in FIGS. 3 and 4 , the rail structure 115 is formed on the inner surface of the guide bar 111 in the vertical direction, and the binding structure 121 formed on both sides of the upper V block 120 is It is preferably seated on the rail structure of the guide bar 111 to change the sliding position in the vertical direction.

In this case, according to this embodiment, one or a plurality of hydraulic cylinders 140 can be mounted, and a U-shaped frame structure can be formed, so that a vertical downward hydraulic press can be configured in various shapes and structures, so that the object to be pressed It is possible to provide a vertical downward hydraulic press with an optimized structure in consideration of the range of compression pressure and the installation environment.

As shown in FIG. 5 , the master die 150 according to the present embodiment is preferably spaced apart by a predetermined angle along the outer circumferential surface of the compression object to have a structure separated into a plurality of pieces. At this time, the master die 150 may press the outer circumferential surface of the compression object by converging the plurality of pieces in the center direction of the compression object according to the change in the lower position of the upper V block 120 .

A plurality of pieces of the master die 150 according to the present embodiment are bound to each other in a sliding rail 156 structure.

In addition, each side of the plurality of pieces of the master die 150 is bound to each other by an elastic member 162 , and by the elastic restoring force of the elastic member 162 according to the change of the upper position of the upper V block 120 . A plurality of pieces are spaced apart from each other by a predetermined interval, and thus may have a structure away from the outer circumferential surface of the object to be compressed.

5, the master die 150 according to the present embodiment will be described in more detail.

The master die 150 according to this embodiment has a specific structure of the lower master die 151, the side master die 152, the lower auxiliary master die 153 and the upper master die 154, and the upper auxiliary master die 155 ) may be a configuration comprising.

The lower master die 151 is configured to be seated in the exact center of the V-shaped groove 161 of the lower V block 110, and an inclined surface structure 151b corresponding to the V-shaped groove 161 is formed on both sides thereof, and the upper The pressing protrusion 151a protruding upward by a predetermined height in the center and having a curved structure corresponding to a partial surface of the outer peripheral surface of the pressing object is formed, and sliding rails 156 may be formed on both sides of the pressing projection.

The side master die 152 is configured to be seated on both sides of the V-shaped groove 161 of the lower V block 110, and at the same time is seated on both sides of the V-shaped groove 161 of the upper V block 120, An inclined surface structure 152b corresponding to the V-shaped groove 161 of the upper V block 120 is formed on the upper surface, and an inclined surface structure corresponding to the V-shaped groove 161 of the lower V block 110 is formed on the lower surface ( 152b) is formed, and the pressing protrusion 152a is formed in the center of the side, protruding by a predetermined length in the direction in which the pressing object is disposed, and having a curved structure corresponding to a partial surface of the outer peripheral surface of the pressing object, and sliding rails on both sides of the pressing projection. It may be a structure in which 156 is formed.

The lower auxiliary master die 153 is configured to be seated simultaneously on the sliding rail 156 of the lower master die 151 and the sliding rail 156 of the side master die 152, and the lower master die 151 on one side. The elastic member 162 bound to the is mounted, and the elastic member 162 bound to the side master die 152 is mounted on the other side, and protrudes by a predetermined length in the direction in which the pressurizing object is disposed. It may be a structure in which a curved structure corresponding to a surface is formed.

The upper master die 154 is configured to be seated in the exact center of the V-shaped groove 161 of the upper V block 120, and an inclined structure 154b corresponding to the V-shaped groove 161 is formed on both sides of the upper master die, and the lower A pressing protrusion 154a protruding downward by a predetermined height in the center to have a curved structure corresponding to a partial surface of an outer peripheral surface of the pressing object is formed, and sliding rails 156 may be formed on both sides of the pressing projection.

In addition, the upper auxiliary master die 155 is a configuration that is seated on the sliding rail 156 of the upper master die 154 and the sliding rail 156 of the side master die 152 at the same time, and the upper master die ( 154) is mounted, an elastic member 162 bound to the side master die 152 is mounted on the other side, and protrudes by a predetermined length in the direction in which the pressurized object is disposed. It may be a structure in which a curved structure corresponding to a partial surface of the outer circumferential surface is formed.

As shown in FIG. 5 , the upper master die 154 is preferably mounted in the V-shaped groove 161 of the upper V block 120 by a disassembly and assembly binding member 157 .

In this case, according to this embodiment, the lower master die 151, the side master die 152, the lower auxiliary master die 153, the upper master die 154, the upper auxiliary master die 155, sliding of a specific structure. By providing the master die 150 including the rail 156 and the elastic member 162, the pressing force caused by the change in the lower position of the upper V block 120 can be evenly distributed along the outer peripheral surface of the compression object and pressurized, Instead of using the unidirectional pressing force according to the prior art, it is possible to compress the object to be compressed using a pressing force applied evenly along the entire outer circumferential surface, thereby providing a vertical downward hydraulic press that can ensure the quality of the compression result.

Meanwhile, as shown in FIG. 6 , the lower V block 110 may be configured to include a block body 112 and a sliding rail 113 having a specific structure.

Specifically, the block body 112 of the lower V block 110 may have a block structure in which a V-shaped groove 161 is formed while longitudinally in the upper central portion. In addition, the sliding rail part 113 is a configuration mounted on both inclined surfaces of the V-shaped groove 161, and the lower surface of the master die 150 is a plate-shaped structure that forms a rail structure so that the sliding position can be changed along the inclined surface. can

In addition, the upper V block 120 may be configured to include a block body portion 122 and a sliding rail portion 123 of a specific structure.

Specifically, the block body 122 of the upper V block 120 may have a block structure in which a V-shaped groove 161 is formed while longitudinally in the lower central portion. In addition, the sliding rail part 123 is a configuration mounted on both inclined surfaces of the V-shaped groove 161, and the upper surface of the master die 150 is a plate-shaped structure that forms a rail structure so that the sliding position can be changed along the inclined surface. can

In some cases, as shown in FIG. 6 , a groove spacing changing part capable of changing the spacing between the sliding rail part 113 of the lower V block 110 and the sliding rail part 123 of the upper V block 120 . (114) can be mounted.

Specifically, the groove spacing changing part 114 of the lower V block 110 is configured to include a screw binding hole 114a, a screw 114b, a rotating handle part 114c and a rail mounting part 114d of a specific structure. can be The screw coupling hole 114a of the groove spacing changing part 114 may have a structure in which the V-shaped grooves 161 of the block body part 112 are recessed by a predetermined depth from both inclined surfaces to both sides. The screw 114b is a configuration that is rotatably mounted to the screw binding hole 114a, and the lateral position of the rail mounting part 114d can be changed by a rotational operation. The rotation handle portion 114c is a configuration mounted on the other end of the screw 114b, is exposed to the outside of one side of the block body portion 112, and can rotate the screw 114b. In addition, the rail mounting portion 114d is a configuration mounted on one end of the screw 114b, and the sliding rail portion 113 is mounted on one side, and the lateral position can be changed by the rotational operation of the screw 114b. .

The groove spacing changing part 124 of the upper V block 110 may be configured to include a screw binding hole 124a, a screw 124b, a rotating handle part 124c, and a rail mounting part 124d having a specific structure. . The screw coupling hole 124a of the groove spacing changing part 124 may have a structure in which the V-shaped grooves 161 of the block body part 122 are recessed by a predetermined depth from both inclined surfaces to both sides. The screw 124b is a configuration that is rotatably mounted to the screw binding hole 124a, and the lateral position of the rail mounting part 124d can be changed by a rotation operation. The rotation handle portion 124c is a configuration mounted on the other end of the screw 124b, is exposed to the outside of one side of the block body portion 122, and can rotate the screw 124b. In addition, the rail mounting portion 124d is a configuration mounted on one end of the screw 124b, and the sliding rail portion 123 is mounted on one side, and the lateral position can be changed by the rotational operation of the screw 124b. .

In this case, according to the present embodiment, by having a groove interval changing unit 114) capable of changing the interval of the V-shaped groove 161) formed in the upper V block 120) and the lower V block 110), the initial pressurization start position is set by the operator. It can be changed according to the intention, and additional compression can be performed by driving the groove interval changing unit 114) during the compression process, so that it is possible to provide a vertical downward hydraulic press that can significantly increase the range of compression.

Meanwhile, as shown in FIG. 7 , a plurality of bent structures may be formed at one end of each master die constituting the master die 150 , that is, a curved structure corresponding to a partial surface of an outer peripheral surface of an object.

In this case, according to the present embodiment, by forming a plurality of bent structures on the curved structure of the master die in contact with the outer circumferential surface of the object to be compressed, the curved structure can be naturally changed according to the size of the outer diameter of the object to be compressed, It is possible to provide a universally operable vertical downward hydraulic press capable of effectively compressing the outer circumferential surface of various sizes of the object to be pressed by being customized according to the size of the outer diameter.

8 is a schematic diagram showing a state of easily monitoring and controlling the vertical top-down hydraulic press according to another embodiment of the present invention using a wireless communication module.

Referring to FIG. 8 , the vertical downward hydraulic press 100 according to the present embodiment may be configured to include a pressure detection unit S, a control unit C, and a wireless communication module M that perform a specific role.

Specifically, the pressure detection unit (S), as a component mounted on the master die 150, may detect the magnitude of the pressure applied from the outer peripheral surface of the compression object in real time and transmit it to the control unit (C).

The control unit (C) may control the operation of the hydraulic cylinder 140 based on the data detected from the pressure detection unit (S) material.

In addition, the wireless communication module (M), as a component built in the control unit (C), in conjunction with the user's smart device through wireless communication, the operation state information of the vertical top-down hydraulic press transmitted from the control unit (C) to the operator It is provided in real time, and it can receive a control signal from the operator's smart device and transmit it to the control unit (C).

In this case, according to the present embodiment, by providing a pressure detecting member, a control unit, and a wireless communication module performing a specific role, it is possible to easily input and control the size of the pressing force according to the intention of the operator, and the operation of the vertical downward hydraulic press A vertical downward hydraulic press can be provided for easy condition monitoring.

In the above detailed description of the present invention, only specific embodiments thereof have been described. However, it is to be understood that the present invention is not limited to the particular form recited in the detailed description, but rather, it is to be understood to cover all modifications and equivalents and substitutions falling within the spirit and scope of the invention as defined by the appended claims. should be

That is, the present invention is not limited to the specific embodiments and descriptions described above, and any person skilled in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims can implement various modifications are possible, and such modifications shall fall within the protection scope of the present invention.

100: vertical downward hydraulic press
110: lower V block
111: guide bar
112: block body part
113: sliding rail unit
114: groove gap change part
114a: screw fastener
114b: screw
114c: rotation handle unit
114d: rail mount
115: rail structure
120: upper V block
121: binding structure
122: block body part
123: sliding rail unit
124: groove gap change part
124a: screw fastener
124b: screw
124c: rotation handle unit
124d: rail mount
130: head block
140: hydraulic cylinder
150: master die
151: lower master die
151a: pressing protrusion
151b: inclined plane structure
152: side master die
152a: pressing protrusion
152b: inclined plane structure
153: lower auxiliary master die
154: upper master die
154a: pressing protrusion
154b: inclined plane structure
155: upper secondary master die
156: sliding rail
157: binding member
161: V-shaped groove
162: elastic member
S: pressure detection unit
C: control
M: wireless communication module

Claims (5)

A V-shaped groove 161 is formed on the longitudinal cross-section in which the lower part of the master die 150 can be seated in the upper central part of the ground or facility to be installed, and a guide bar extending upward by a predetermined height on both sides ( 111) is mounted lower V block (110);
A V-shaped groove 161 on the longitudinal section in which the upper part of the lower V block 110 can be positioned so as to be changed in the vertical direction along the guide bar 111, and the upper part of the master die 150 can be seated in the lower central part. is formed, the upper V block 120 having a binding structure 121 coupled to the guide bar 111 on both sides thereof;
A head mounted with a hydraulic cylinder 140 mounted on the upper end of the guide bar 111, binding both guide bars 111 in an integrated structure, and changing the vertical position of the upper V block 120 on the lower surface. block 130; and
A master of a structure that is seated in the lower V-shaped groove 161 and the upper V-shaped groove 161 at the same time, and presses the outer peripheral surface of the object to be pressed in 8 directions spaced apart by a predetermined angle according to the downward driving of the upper V block 120 die 150;
including,
The lower V block 110,
Block body portion 112 having a V-shaped groove 161 longitudinally formed in the upper central portion; and
a sliding rail portion 113 of a plate-shaped structure mounted on both inclined surfaces of the V-shaped groove 161 and forming a rail structure such that the lower surface of the master die 150 can change the sliding position along the inclined surface; and
a groove spacing changing part 114 mounted inside the block body part 112 and changing the position of the sliding rail part 113 toward the central part;
including,
The groove interval changing unit 114,
The V-shaped grooves 161 of the block body 112 are recessed by a predetermined depth from both sides of the inclined surfaces to both sides of the screw binding hole 114a;
a screw 114b that is rotatably mounted to the screw binding hole 114a and changes the lateral position of the rail mounting portion 114d by a rotational operation;
a rotation handle part 114c mounted on the other end of the screw 114b, exposed to the outside of one side of the block body 112, and rotating the screw 114b; and
a rail mounting part (114d) mounted on one end of the screw (114b), mounted on one side of the sliding rail part (113), and lateral position changed by the rotational operation of the screw (114b);
A vertical downward hydraulic compactor comprising a.
delete delete According to claim 1,
The master die 150,
It is a structure separated into a plurality of pieces spaced apart by a certain angle along the outer circumferential surface of the object to be pressed,
By changing the lower position of the upper V block 120, a plurality of pieces converge toward the center of the object to be compressed, thereby pressing the outer peripheral surface of the object to be compressed,
A plurality of pieces of the master die 150 are bound to each other in a sliding rail 156 structure,
Each side of the plurality of pieces of the master die 150 is bound to each other by an elastic member 162,
A vertical downward hydraulic press, characterized in that the plurality of pieces are spaced apart at regular intervals by the elastic restoring force of the elastic member 162 according to the change of the upper position of the upper V block 120, thereby moving away from the outer circumferential surface of the object to be compressed.
According to claim 1,
The master die 150,
It is seated in the exact center of the V-shaped groove 161 of the lower V block 110, and an inclined structure 151b corresponding to the V-shaped groove 161 is formed on both sides of the lower V block 110, and protrudes upward by a predetermined height in the upper center. a lower master die 151 in which a pressing protrusion 151a having a curved structure corresponding to a partial surface of an outer peripheral surface of the pressing object is formed, and sliding rails 156 are formed on both sides of the pressing protrusion;
It is seated on both sides of the V-shaped groove 161 of the lower V block 110, and at the same time seated on both sides of the V-shaped groove 161 of the upper V block 120, and the upper V block 120 on the upper surface. An inclined structure 152b corresponding to the V-shaped groove 161 of The pressing protrusion 152a protruding by a predetermined length in the direction in which the pressing object is disposed and having a curved structure corresponding to a partial surface of the outer peripheral surface of the pressing object is formed, and sliding rails 156 are formed on both sides of the pressing projection. 152);
An elastic member 162 that is simultaneously seated on the sliding rail 156 of the lower master die 151 and the sliding rail 156 of the side master die 152 and is bound to the lower master die 151 is mounted on one side thereof. and an elastic member 162 bound to the side master die 152 is mounted on the other side thereof, and protrudes by a predetermined length in the direction in which the pressurized object is disposed. master die 153;
It is seated in the exact center of the V-shaped groove 161 of the upper V block 120, and an inclined structure 154b corresponding to the V-shaped groove 161 is formed on both sides of the upper V block 120, and protrudes downward by a predetermined height in the lower center. an upper master die 154 in which a pressing protrusion 154a having a curved structure corresponding to a partial surface of an outer circumferential surface of the pressing object is formed, and sliding rails 156 are formed on both sides of the pressing protrusion; and
An elastic member 162 that is simultaneously seated on the sliding rail 156 of the upper master die 154 and the sliding rail 156 of the side master die 152 and is bound to the upper master die 154 is mounted on one side thereof. An elastic member 162 bound to the side master die 152 is mounted on the other side, and it protrudes by a predetermined length in the direction in which the pressurized object is disposed. master die (155);
A vertical downward hydraulic compactor comprising a.

Images