KR101992601B1 - Another liquid mixing device for insulation block of ship forepeak - Google Patents

Abstract

Two-liquid mixing equipment for the insulation block of a ship cargo hold provided by the present invention comprises: a principal agent unit which has a principal agent drum mounted thereon and supplies a principal agent inside the principal agent drum by pressurizing the inside of the installed principal agent drum; a curing agent unit which has a curing agent drum mounted thereon and supplies a curing agent inside the curing agent drum by pressurizing the inside of the curing agent drum; a heating unit which is coupled to the circumference of the principal agent drum of the principal agent unit and the curing agent drum of the curing agent unit to heat the principal agent and the curing agent; and a spray unit which is connected to the principal agent unit and the curing agent unit, mixes the principal agent and the curing agent supplied from the principal agent unit and the curing agent unit, and applies the mixed liquid onto the insulation block. Therefore, the replacement work of the principal agent drum and the curing agent drum is very simple, the inside of the principal agent drum can be heated evenly, the attachment and detachment of the heating unit are very easy, and a follower plate can be smoothly separated from the principal agent drum.

Description

Another liquid mixing device for insulation block of ship forepeak}

The present invention relates to a two-liquid mixing device for a cargo hold insulation block for ships, and more particularly, the replacement of the main drum and the hardener drum is very simple, can uniformly heat the inside of the main drum, the removal of the heating portion is very easy The present invention relates to a lyotropic liquid mixing device for a cargo hold insulation block capable of smoothly separating a follower plate from a main drum.

Generally, the two-liquid mixing device refers to a device for mixing and discharging two liquids, which are liquid substances of different types, at a predetermined flow rate and pressure, without changing the mixing ratio such as high viscosity epoxy, urethane, silicone, and paint. It is used to mix and supply high-viscosity resins and to mix and supply special materials such as main materials and curing agents.

The liquid-liquid mixing and discharging device is widely used because the discharging amount of the discharging amount is small, and the metering and precise weighing are possible by mixing and discharging the mixed resin material or the main material of the powder and the curing agent in an accurate amount. .

The conventional liquid-liquid mixing device for mixing and discharging such a subject and a curing agent comprises a body portion, a supply transfer portion, a supply portion, a pumping portion, a mixed discharge portion, and a control portion.

The body part is provided with material seating parts so that the material cans of the solution are respectively seated in order to discharge the liquid solution, and a lower transfer wheel is provided.

The feed transfer part is for lifting the supply flange of the supply part located inside the raw material can, the transfer cylinder installed in the body portion, the transfer fixing plate installed on the upper end of the transfer cylinder, and the upper end is fixed to the transfer fixing plate and the lower end It is connected to the supply flange consists of a transfer bar for raising and lowering the supply flange during operation of the transfer cylinder.

The supply part is provided inside the raw material can and is connected to the feed bar of the feed transfer part to lift the inside of the raw material can during operation of the transfer cylinder, and pressurize the liquid in the raw material can to the pumping part side when descending by the transfer cylinder. Sealing ring, which is installed around the flange and the supply flange to maintain airtightness between the supply flange and the transfer can, and the heating that is installed in the supply flange to heat it when the liquid inside the raw material can passes through the supply flange and is supplied to the pumping part. It is made of wealth.

The pumping part is connected to the supply flange of the supply part so that the liquefied liquid inside the raw material can is pumped to the mixed discharge part side through the supply flange, and is installed in the transfer bar of the supply transfer part to be lifted up and down together when the transfer bar is raised and lowered. It is connected to the drive motor for driving the gear pump, and a coupling provided between the motor shaft of the drive motor and the drive shaft of the gear pump.

The mixed discharging unit is connected to a supply flange to supply a main liquid and a curing agent, a mixing unit to mix the liquefied liquid connected to the liquefied liquid supply unit, and a discharge nozzle connected to the mixing unit to discharge mixed liquefied liquid. And a discharge pressure sensor installed in a transfer line between the supply flange and the liquid supply part to sense the discharge pressure of the liquid supplied to the discharge nozzle, and a pressure gauge connected to the discharge pressure sensor to display the measured discharge pressure.

The control unit is connected to the supply transfer unit, the supply unit, and the mixed discharge unit to control them.

The two-liquid mixing device for a conventional cargo hold insulation block of such a configuration is operated as follows.

First, the feed cylinder is operated to raise the feed flange to the uppermost side by operating the feed cylinder. The main raw material can and the hardener raw material can are respectively placed on the raw material receiving parts of the body part. When the raw material can is seated on the body, the feed cylinder of the feed transfer part is operated to transfer the supply flange to the lower side of the raw material can.

Then, the pumping part of the supply unit is driven to supply the main body and the curing agent inside the raw material candle to the mixed discharge part side. The main material and the hardener inside the raw material can are smoothly discharged to the mixed discharge part by the supply transfer part and the driving part of the raw material can, and the raw material can is pumped by pressurizing the inside of the raw material can while the supply flange of the feeding part is lowered. The main subject and the curing agent are pumped back to the mixed discharge part side.

The main agent and the curing agent inside the raw material can are heated while passing through the heating portion while being pumped to the mixed discharge portion after passing through the supply flange by the feed transfer portion and the feed portion. The heated main body and the hardener are not only smoothly supplied to the mixed discharge part because of increased fluidity, but also easily stirred at the mixed discharge part. The main body and the hardener are mixed while passing through the mixing portion of the mixed discharge portion, and the mixed lyotropic liquid mixture is discharged to the outside through the discharge nozzle.

Therefore, the mixed discharging unit discharges the lyotropic liquid mixture to the upper surface of the insulating block while the insulating block is transferred along the conveying conveyor.

By the way, the conventional liquid-liquid mixing apparatus for ship cargo insulation block, some problems arise.

First, it was not easy to replace the main raw material can and the curing agent raw material can. The raw material cans using both the main material and the hardener are relatively light, so it is relatively easy to separate them from the raw material seating part of the body. However, the new main material and hardener cans are heavy and require separate equipment such as a forklift to settle on the raw material seating part of the body. It was.

Second, the conventional heater unit is fixed to the supply flange of the supply transfer portion is a structure for heating the main material and the curing agent passing through the supply flange.

The heater unit is a structure for heating the main material and the curing agent passing through the supply flange, and is not a structure for heating the entire inside of the raw material can. Therefore, the main body and the curing agent inside the raw material can not be heated sufficiently until it is supplied to the supply flange and thus the main and hardener inside the raw material can can not be smoothly supplied to the supply flange side. In addition, the conventional heater unit is fixedly installed in the supply flange, it was not easy to separate and repair when the heater unit failure.

Third, when the supply flange descends to the bottom of the raw material can, and the main body and the hardener inside of the raw material can be used up, the supply flange must be raised to separate the raw material can from the raw material can. That is, a vacuum is formed in the space between the lower surface of the supply flange and the raw material can. Therefore, even when the transfer cylinder is operated to separate the supply flange, the supply flange is not easily separated from the raw material can, and an excessive load acts on the transfer cylinder, causing a failure of the transfer cylinder.

Republic of Korea Patent No. 10-0692234 Republic of Korea Patent No. 10-0704940

SUMMARY OF THE INVENTION An object of the present invention for solving the above problems is to provide a lyotropic liquid mixing apparatus for a ship cargo insulation block so that replacement of the main drum and the hardener drum is very simple.

Another object of the present invention is to heat the inside of the main drum uniformly, the detachment of the heating part is very simple, the maintenance of the heating part is very easy, and when the heating part is mounted on the main drum elastically to the outer peripheral surface of the main drum It is to provide a two-liquid mixing device for the ship cargo insulation block to be in close contact.

Still another object of the present invention is to provide a lyotropic liquid mixing apparatus for a ship cargo insulation block allowing the follower plate to be smoothly separated from the main drum.

The liquid-liquid mixing device for a cargo hold insulation block of the present invention for achieving the above object, the main part is the main drum is seated and seated on the inside of the main drum pressurized to supply the main subject inside the main drum; A curing agent part on which the curing agent drum is seated and pressurizing the inside of the curing agent drum to supply the curing agent inside the curing agent drum; A heating unit coupled to the main drum of the main body and the hardener drum of the hardening unit to heat the main body and the hardener; A spraying portion connected to the main portion and the curing agent portion to mix the main portion and the curing agent supplied from the main portion and the curing agent portion and apply the mixed mixture to the insulating block; The heating unit includes a first heating unit including a first heater covering a portion of an outer circumferential surface of the main drum and a first heating cover surrounding the first heater, and a second heater that forms a pair with the first heating unit and surrounds a portion of the outer circumferential surface of the main drum. And a second heating part including a second heating cover surrounding the second heater, a tension coil tension coil spring connected to a corresponding end of the first heating part and the second heating part, and a detachable piece provided on the first heating part. A detachable lever provided on and detached from the detachable piece, the heating unit being detachable from the outer circumferential surface of the main drum; The outer circumferential length of the main drum is longer than the sum of the circumferential length of the inner circumferential surface of the first heating portion and the circumferential length of the inner circumferential surface of the second heating portion and the length of the tension coil spring, so that the first heating portion and the second heating portion are formed on the outer circumferential surface of the main drum. When fastened to the detachable lever, the tension coil spring is tensioned, characterized in that the first heating portion and the second heating portion is provided to be elastically in close contact with the outer peripheral surface of the main drum.

Another feature of the lyotropic liquid mixing apparatus for ship cargo insulation block of the present invention, the viscous fluid guide grooves are formed in the raw material guide surface, the viscous fluid guide grooves are radial on the raw material guide surface along the direction of the viscous fluid flow when the viscous fluid is pressurized The cross section of the viscous fluid guide groove has a semicircular shape, and when the viscous fluid is pressurized, a part of the viscous fluid is led to the outlet side of the follower plate along the viscous fluid guide groove, so that the viscous fluid is pressurized by the follower plate. It is provided to guide the transfer to the outlet side of the viscous fluid guide groove is coated with a frictional force reducing coating layer.

Another feature of the lyotropic liquid mixing apparatus for ship cargo insulation block of the present invention, the lower base frame, drum picking to prevent the main drum from flowing while seated on the lower step of the main drum when the main drum is seated on the lower base frame A plate is provided, and an elevating part is provided between the lower base frame and the drum fixing plate to raise and lower the drum fixing plate. When the main drum is transferred to the upper side of the lower base frame, the drum fixing plate is lower than the lower end of the main drum. When the main drum is positioned on the lower base frame, the drum fixing plate is lifted to be seated on the lower step of the main drum.

In the present invention as described above, when the main drum seated on the auxiliary seating portion pushes the lower base frame side, the feed roller is idle while the main drum of weight is transferred to the lower base frame side, the lower base frame along the drum guide bar of the lower base frame It is transported to the top and seated on the drum fixing plate. Therefore, the operator can simply slide the main drum of the weight to be seated on the lower base frame, it can be performed in a stable state because it is not moved by the drum fixing plate in the state seated on the lower base frame.

In addition, the heating unit is composed of a first heating unit and a second heating unit to be attached to the outer peripheral surface of the main drum. The outer circumferential length of the main drum is longer than the sum of the circumferential length of the inner circumferential surface of the first heating part and the circumferential length of the inner circumferential surface of the second heating part and the length of the tension coil spring, so that the first heating part and the second heating part of the main drum When fastened to the outer circumferential surface by a detachable lever, the tension coil spring is tensioned is provided so that the first heating portion and the second heating portion elastically close to the outer peripheral surface of the main drum. Therefore, since the heating part is fastened around the main drum, the inside of the main drum can be heated uniformly, and the detachment of the heating part is very simple, so the maintenance of the heating part is very easy, and when the heating part is mounted on the main drum, the tension coil spring is used. Since the elastic contact with the outer peripheral surface of the main drum, the heat of the heating portion is transmitted to the main drum stably.

Further, viscous fluid guide grooves are formed on the material guide surface of the follower plate. These viscous fluid guide grooves are radially formed on the raw material guide surface along the direction in which the viscous fluid flows when the viscous fluid is pressurized, and the cross section of the viscous fluid guide groove is semicircular. Therefore, when the viscous fluid is pressurized, a part of the viscous fluid is guided to the outlet side of the follower plate along the viscous fluid guide groove, thereby guiding the pressurized viscous fluid to be transferred to the outlet side of the follower plate, so that the viscous fluid guides the raw material guide surface. Follow the guide to ensure a smooth discharge. A frictional force reducing coating layer may be applied to the viscous fluid guide groove. Therefore, when the follower plate is pressurized, the topic entered into the viscous fluid guide groove flows faster than the topic located outside the viscous fluid guide groove, thereby guiding the topic to be discharged quickly.

The lower base frame further includes an elevating unit for elevating the drum fixing plate. Therefore, when the main drum is moved to the lower base frame side, the drum fixing plate remains lowered, and when the main drum is seated on the lower base frame, the lift unit is driven to raise the drum fixing plate to rest on the lower step of the main drum. . Therefore, the main drum seated on the lower base frame is firmly supported.

1 is a schematic front view showing a two-liquid mixing device for a ship cargo insulation block of the present invention.
FIG. 2 is a schematic side view of FIG. 1
3 is a schematic plan view of FIG.
Figure 4 is a partial front view showing the lower base frame and drum fixing plate
5 is a plan view of FIG.
6 is a schematic front view showing a main part and a hardener part;
7 is a side view of FIG. 6
8 is a partially enlarged cross-sectional view showing a non-return valve.
9 is a front view and a side view showing the injection unit
10 and 11 are a cross-sectional view and a bottom view showing another embodiment of the follower plate
12 is a fragmentary front view showing another embodiment of a drum fixing plate.
13 and 14 are schematic front and back views showing the heating portion
15 and 16 are schematic front and side views showing the pickup portion;
17 and 18 are schematic perspective views and side views showing the cleaning unit
19 and 20 are schematic front and side views showing the insulating block laminated portion
Figure 21 is a schematic front view showing a horizontal conveying means of the insulating block laminated portion
22 is a partially enlarged front view of the spacer supply unit;
23 and 24 are schematic front view and a plan view showing the adiabatic block turning portion
25 is a partially enlarged front view of the adiabatic block turning part;
26 is a schematic plan view of the conveying conveyor unit;
27 is a schematic side view of a turning conveyor;

Specific features and advantages of the present invention will become more apparent from the following description taken in conjunction with the accompanying drawings.

1 is a schematic front view showing a lyotropic liquid mixing apparatus for a ship cargo insulation block of the present invention, Figure 2 is a schematic side view of Figure 1, Figure 3 is a schematic plan view of FIG. Figure 4 is a partial front view showing a lower base frame and drum fixing plate, Figure 5 is a plan view of Figure 4, Figure 6 is a schematic front view showing a main portion and a hardener portion. FIG. 7 is a side view of FIG. 6, FIG. 8 is a partially enlarged cross-sectional view showing a non-return valve, and FIG. 9 is a front view and a side view showing an injection unit. 10 and 11 are a cross-sectional view and a bottom view showing another embodiment of the follower plate, Figure 12 is a partial front view showing another embodiment of the drum fixing plate, Figures 13 and 14 are a schematic front view showing a heating portion and Back view. 15 and 16 are schematic front and side views showing the pick-up portion, FIGS. 17 and 18 are schematic excerpts and side views showing the cleaning portion, and FIGS. 19 and 20 are schematic front and side views showing the insulating block stacking portion. FIG. 21 is a schematic front view showing a horizontal transfer means of the insulating block stacking portion, FIG. 22 is a partially enlarged front view showing a spacer supplying portion, and FIGS. 23 and 24 are schematic front views and a plan view showing the insulating block turning portion. 25 is a partially enlarged front view showing the adiabatic block turning part, FIG. 26 is a schematic plan view showing a conveying conveyor part, and FIG. 27 is a schematic side view showing a turning conveyor.

The lyotropic liquid mixing apparatus for a ship cargo insulation block of the present invention comprises a main portion 100, a hardener portion 200, an injection portion 400, a heating portion 300.

The main body 100 supplies the main body inside the main drum 101 by pressing the inside of the main drum 101 on which the main drum 101 is seated and seated. The main body 100 includes a main drum 101 having a main body stored therein and a step 101a formed at a lower end thereof, and a lower base frame 110 on which the main drum 101 is seated.

The upper surface of the lower base frame 110 is provided with a drum guide bar 111 for linearly contacting the lower surface of the main drum 101 to smoothly transport the main drum 101 of the weight, the lower base frame 110 In the center of the main drum 101 is provided with a drum fixing plate 112 that is supported on the step (101a) of the main drum 101 when seated on the lower base frame (110). A lifting bolt 116 is provided at an upper edge portion of the lower base frame 110, a caster 114 is provided below the lower base frame 110, and a level foot 115 is provided at one side of the caster 114. do.

One side of the lower base frame 110 is provided with an auxiliary seating portion 117. The spare main drum 101 is seated in the auxiliary seating part 117. The auxiliary seating portion 117 is provided so that a plurality of feed roller 118 is idle. Therefore, when the operator pushes the main drum 101, the feed roller 118 is idle while the main drum 101 of the weight is transferred.

An air lifter cylinder 120 is installed in the lower base frame 110. Air lifter cylinder 120 is installed in a plurality of lower base frame 110 to elevate the follower plate 130 to be described later, so that the main body in the main drum 101 is pumped toward the injection unit 400 through the supply line 172. do. The upper frame 122 is coupled to the upper end of the cylinder rod 121 of the air lifter cylinder 120 to be elevated during operation of the air lifter cylinder 120.

An upper end of the distance rod 133 is coupled to the upper frame 122, and a follower plate 130 is coupled to a lower end of the distance rod 133. The follower plate 130 is coupled to the follower plate O-ring 132 so as to be in close contact with the inner circumferential surface of the main drum 101 around the outer circumferential surface, and the lower surface of the follower plate 130 is tapered in a tapered form toward the center side from the outer circumference. Guide surface 131 is formed.

The upper part of the follower plate 130 is provided with a discharge block 134 for guiding the main pressurized along the raw material guide surface 131 to be discharged to the injection unit 400 side through the supply line 172, the discharge block ( The gear pump 140 is installed on the upper portion of the discharge block 134 so that a vacuum suction force is formed in the discharge block 134. The discharge block 134 is supported on the casing of the air lifter cylinder 120 by the rework clip 123.

The connection plate 153 is coupled to the distance rod 133, and the motor 150 is installed at the connection plate 153. The motor shaft 151 of the motor 150 and the gear pump shaft 141 of the gear pump 140 are coupled by the down coupling 152 and the gear pump coupling 142. A motor fixing housing 144 is installed between the motor 150 and the gear pump 140 to support them.

The non-return valve 160 is coupled to the discharge block 134 so that the main body introduced into the discharge block 134 is supplied to the injection unit 400 and prevented from flowing backward in the opposite direction. The heating hose 168 is connected to the non-return valve 160 to heat the main body supplied to the injection unit 400 so as not to cool while passing through the heating hose 168.

The non-return valve 160 includes a valve body 161, a backflow prevention ball 165, a pressure spring 166, and a stopper 167.

The valve body 161 is connected between the discharge block 134 and the heating hose 168 and connects the inlet 163 through which the main body is introduced, and the outlet 164 through which the main body is discharged, the inlet 163 and the outlet 164. A flow path 162 is formed. The non-return ball 165 is provided in the flow path 162 of the valve body 161 to open and close the inlet 163. The pressure spring 166 is built in the valve body 161 to elastically support the backflow prevention ball 165 toward the inlet 163. The stopper 167 is coupled to the valve body 161 to be embedded in the valve body 161 to the backflow prevention ball 165 and the pressure spring 166.

An air vent unit 170 is connected to the raw material guide surface 131 of the follower plate 130 so as to inject or discharge external air into the follower plate 130. The air vent unit 170 is provided with a degassing lever 171 to open and close the air vent unit 170.

10 and 11 are schematic cross-sectional views and bottom views of another embodiment of the follower plate 130. In the raw material guide surface 131 of the follower plate 130, viscous fluid guide grooves 135 are formed, and the viscous fluid guide grooves 135 are raw material guide surfaces 131 along the direction in which the viscous fluid flows when the viscous fluid is pressurized. ) Is formed radially, the cross section of the viscous fluid guide groove 135 is formed in a semicircular shape.

Such a follower plate 130 allows a part of the viscous fluid to be guided to the outlet side of the follower plate 130 along the viscous fluid guide groove 135 when the viscous fluid is pressurized, so that the pressurized viscous fluid is the follower plate 130. To be guided to the exit side of the.

A frictional force reducing coating layer may be applied to the viscous fluid guide groove 135 of the follower plate 130.

12 is a schematic partial excerpt front view showing another embodiment of the drum fixing plate 112. When the main drum 101 is seated on the lower base frame 110, the lower base frame 110 is mounted on the lower step 101a of the main drum 101 to prevent the main drum 101 from flowing. A fixing plate 112 is provided.

An elevating part 113 is provided between the lower base frame 110 and the drum fixing plate 112 to elevate the drum fixing plate 112, and the main drum 101 is transferred to the upper side of the lower base frame 110. When the drum fixing plate 112 is positioned lower than the lower end of the main drum 101 and the main drum 101 is seated on the lower base frame 110, the drum fixing plate 112 is raised to It is provided to be seated on the lower step (101a) of the drum (101). The lifting unit 113 may be formed of a lifting cylinder.

The curing agent part 200 supplies the curing agent inside the curing agent drum 201 by pressing the inside of the curing agent drum 201 on the curing agent drum 201.

The curing agent portion 200 is the same as the configuration and operation of the main portion, and differs only in that the curing agent is stored in the curing agent drum instead of the subject, and thus the detailed description of the curing agent portion 200 will be omitted.

The injection unit 400 is connected to the main drum 101 of the main unit 100 and the hardener drum 201 of the hardener unit 200 to supply the main and hardeners, to mix and mix the supplied main and hardeners. The lyotropic liquid mixture is applied to the insulating block 10.

The injection part 400 is connected to the main part 100 and the hardener part 200 so that the main part and the hardener supplied from the main part 100 and the hardener part 200 are supplied to the nozzle 409 side and vice versa. A non-return valve 401 for blocking the reverse flow in the direction, a mixing block 403 connected to the non-return valve 401 and supplied from the main body and a hardener and mixed therein, and installed in the mixing block 403. And a heater 404 for heating the mixing block 403, a rotary fitting 402 connected to the non-return valve 401 and the mixing block 403, and a mixing block 403 connected to the mixing block 403. The mixing tube 407 to which the lyotropic liquid mixture flows into is supplied, the terminal nipple 406 connecting the mixing block 403 and the mixing tube 407, and the mixing tube 407 to be installed inside the mixing tube 407. A stick mixer 408 for mixing the lyotropic liquid solution introduced into the mixture and the lyotropic liquid mixture by being coupled to an end portion of the mixing tube 407. The nozzle 409 is applied to the coated surface of the insulating block 10.

The heating part 300 is coupled around the main drum 101 of the main part 100 and the hardener drum 201 of the hardener part 200 to heat the main part and the hardener.

The heating unit 300 includes a first heating unit 301 including a first heater 303 surrounding a part of an outer circumferential surface of the main drum 101 and a first heating cover 302 surrounding the first heater 303. , A second heating made of a pair of first heating parts 301 and comprising a second heater 306 surrounding a part of the outer circumferential surface of the main drum 101 and a second heating cover 305 surrounding the second heater 306. Attachment part 309 provided in the part 304, the tension coil spring 310 connected to the corresponding end part of the 1st heating part 301, and the 2nd heating part 304, and the 1st heating part 301. ) And a detachable lever 308 provided at the second heating unit 304 and detachable from the detachable piece 309, so that the heating unit 300 is detachably attached to the outer circumferential surface of the main drum 101.

Here, the outer circumferential length of the main drum 101 is longer than the sum of the circumferential length of the inner circumferential surface of the first heating part 301 and the circumferential length of the inner circumferential surface of the second heating part 304 and the length of the tension coil spring 310. do. Therefore, when the first heating part 301 and the second heating part 304 are fastened to the outer circumferential surface of the main drum 101 with the detachable lever 308, the tension coil spring 310 is tensioned and the first heating part ( 301 and the second heating unit 304 is provided to be in close contact with the outer peripheral surface of the main drum 101 elastically.

The pick-up unit 500 grips the manufactured insulating block 10 and seats it on the automatic transfer line.

The pickup 500 includes a pickup frame 510 installed on one side of the transfer conveyor 900, a horizontal transfer rail 511 installed on the pickup frame 510, and a horizontal transfer rail 511. It is coupled to the horizontal transport frame 520 reciprocating along the horizontal transport rail 511, and installed in the horizontal transport frame 520 is reciprocated in the horizontal direction with the horizontal transport frame 520 and the insulating block 10 The pick-up lift cylinder 540 for lifting and lowering, the pad fixing plate 550 fixed to the cylinder rod 541 of the pick-up lift cylinder 540 and driven up and down by the pick-up lift cylinder 540, and the pad fixing plate 550. The vacuum pad 570 is installed and adsorbs the adiabatic block 10, and is installed on the pad fixing plate 550 and connected to the vacuum pad 570 to form a vacuum on the vacuum pad 570 to add a suction force ( 560, the pickup guide 580 is fixed to the horizontal transfer frame 520, the pickup guide 580 Are fixed on the pad and the lower fixed plate coupled to beads 550 is provided with a pick-up guide bar 581 for guiding the elevation of the pad fixing plate 550. The

The horizontal transfer cylinder 530 is fixed to the upper portion of the horizontal transfer frame 520. The horizontal transfer cylinder 530 is moved in the horizontal direction with the horizontal transfer frame 520, the end of the cylinder rod 531 is fixed to the rod fixing end 532 of the pickup frame 510, the cylinder rod 531 ), The horizontal transfer frame 520 is reciprocated along the horizontal transfer rail.

The conveying conveyor unit 900 is installed along the automatic conveying line to convey the insulating block 10 picked up by the pick-up unit 500 along the automatic conveying line. The transfer conveyor 900 includes an X-axis transfer conveyor 910, a Y-axis transfer conveyor 920, and a turning conveyor 930.

The X-axis transfer conveyor 910 transfers the insulating block 10 picked up by the pickup unit 500 via the cleaning unit 600 and the injection unit 400.

The Y-axis conveying conveyor 920 is installed on one side of the X-axis conveying conveyor 910 so as to be orthogonal to the X-axis conveying conveyor 910, so that the insulating block 10 via the cleaning part 600 and the spraying part 400 is disposed. Transfer to the insulating block laminated portion 700 side.

The turning conveyor 930 is installed between the X-axis conveying conveyor 910 and the Y-axis conveying conveyor 920, the Y-axis conveying conveyor 920 to the adiabatic block 10 transferred along the X-axis conveying conveyor 910. To be transported.

The turning conveyor 930, a turning conveyor frame 931 is installed between the X-axis conveying conveyor 910 and the Y-axis conveying conveyor 920, and a plurality of X-axis conveying conveyor arranged on the turning conveyor frame 931 The X-axis feed roller 932 for transferring the insulation block 10 transferred along the 910 to be seated on the upper portion of the turning conveyor 930, and one end of the turning conveyor frame 920 opposite to the Y-axis feed conveyor 920 931 is coupled to the hinge shaft (934) on the upper side of the Y-axis feed roller angle adjustment bracket (933) and the other end is provided to be rotated in the upward direction, coupled to the Y-axis feed roller angle adjustment bracket (933) Y-axis feed rollers 935 for transferring the insulating block 10 located on the feed roller 932 to the Y-axis feed conveyor 920, and a turning conveyor frame 931 are installed on the Y-axis feed roller angle control bracket. (933) is connected to the Y-axis feed roller angle adjustment bracket (933) hinged shaft It consists of an angle adjustment cylinder 936 for rotating upwards about the center (934).

Such turning conveyor 930, when the Y-axis feed roller angle adjustment bracket 933 is in a horizontal state, the upper end of the Y-axis feed rollers 935 is located below the top of the X-axis feed roller 932 to insulate The bottom surface of the block 10 is in contact with the X-axis feed roller 932, the Y-axis feed roller 935 when one end of the Y-axis feed roller angle adjustment bracket 933 is raised by operating the angle adjustment cylinder 936 The top of the) is positioned above the top of the X-axis feed roller 932 so that the bottom surface of the insulating block 10 is provided to contact the Y-axis feed rollers (935).

The cleaning unit 600 is installed on the upper portion of the conveying conveyor 900 to clean the mixed liquid coating surface of the insulating block 10 to be transferred along the X-axis conveying conveyor 910.

The cleaning unit 600 is installed on the transfer conveyor 900 of one side of the pickup 500, the mixed liquid application surface of the insulating block 10 passes through the air distribution pipe 601 is supplied with air is connected to the air tank And a cleaning nozzle 602 installed in a plurality of air distribution pipes 601 and supplied with air to the air distribution pipes 601 to clean the mixed liquid coating surface of the insulating block 10, and an air tank and an air distribution pipe ( 601 is connected to the air supply hose 603 for supplying air from the air tank to the air distribution pipe 601.

The insulating block stacking part 700 is installed at the upper side of the other side of the conveying conveyor part 900 and grips the insulating block 10 on the upper part of the conveying conveyor part 900 to which the mixed liquid is applied by the spraying part 400. Stacked on, but the plurality of spacers (743) are dropped on the upper surface of the stacked insulating block 10 so that the mixed solution is not buried in the insulating block 10, the mixed solution of the stacked insulating block 10 is stacked and placed The stacked insulating block 10 is to be seated on the upper surface of the spacers (743).

The thermal insulation block stack 700 is coupled to the stacking frame 701, the stacking portion horizontal transport rail 702 and the stacking portion horizontal transport rail 702 installed on the stacking frame 701. The stacking unit horizontal transfer plate 703 which is slide-transported in the horizontal direction along the stacking unit horizontal transport rail 702, and is fixed on the stacking unit horizontal transfer plate 703 and transported along the horizontal direction together with the stacking unit horizontal transfer plate 703. The gripper mounting plate 710 which is positioned inside the stacking lift driving motor 704 and connected to the stacking lift driving motor 704 and is elevated when driving the stacking lift driving motor 704 is driven. ) Is provided.

In addition, the insulating block laminated part 700 is connected to the laminated lifting drive motor 704, the driving pulley 705 receives the rotational power, and the guide pulley 706 fixed on the laminated horizontal transfer plate 703. And, one end is wound on the driving pulley 705, and the other end is fixed to the gripper mounting plate 710 via the guide pulley 706 to lift and lower the gripper mounting plate 710 when driving the laminated lifting driving motor 704. It is coupled to the elevating belt 707, the gripper horizontal transfer rail 720 and the gripper horizontal transfer rail 720 which is installed on the bottom of the gripper mounting plate 710 in the horizontal direction along the gripper horizontal transfer rail 720 A gripper 721 holding the insulating block 10 while being transported, and a fixing bracket 722 fixed to the bottom of the gripper mounting plate 710 are provided.

In addition, the insulating block laminated portion 700, one end is coupled to the fixing bracket 722 and the other end of the operation cylinder rod 724 is coupled to the gripper 721, the gripper 721 is the gripper horizontal transfer rail 720 The gripper operation cylinder 723 and the guide rod guide 711 coupled to the stacking portion horizontal transfer plate 703 and the guide rod guide 711 slide so as to slide along the lower side of the gripper installation plate 710. Mounting plate lifting guide rod 712 coupled to the guide to guide the lifting of the gripper mounting plate 710, laminated horizontal drive plate 703 is installed on the upper portion of the horizontal transfer plate 703, laminated horizontal drive motor The driving pulley 731 connected to the motor shaft of the motor 730 and the upper part of the laminated horizontal transfer plate 703 are connected to the drive pulley 731 of the horizontal laminated motor 730 by a driving belt 733. The drive timing pulley 732 and the upper part of the laminated horizontal transfer plate 703 are installed on the drive timing pulley 732. An electric timing pulley 734 connected to receive the rotational power of the driving timing pulley 732 and one end fixed to one end of the laminated horizontal transfer plate 703, and the driving timing pulley 732 and the electric timing pulley 734 are connected to each other. A timing belt for transmitting the laminated part horizontal transfer plate 703 along the laminated horizontal transfer rail 702 when the other end is fixed to the other end of the laminated horizontal transfer plate 703 so that the laminated horizontal transfer motor 730 is driven. 735 and a spacer supply unit 740 for supplying a plurality of spacers 743 to the upper surface of the stacked insulating block 10 when the insulating block 10 installed on the gripper mounting plate 710 is loaded with the mixed liquid. )

The spacer supply unit 740 is provided on the gripper mounting plate 710 and the upper and lower parts of the cartridge 742, a plurality of spacers 743 that are stacked and stored in the cartridge 742, the lower portion of the cartridge 742 Rotational power of the spacer supply motor 741 is transmitted by being connected to the supply load plate 751, the spacer supply motor 741 installed on the supply load plate 751, and the spacer supply motor 741. The driving pulley 744, the electric pulley 746 which is installed to rotate on the supply load plate 751, and the electric belt 745 fastened to the driving pulley 744 and the electric pulley 746 are provided.

In addition, the spacer supply unit 740 includes a second stopper 749 and a first stopper 747.

The second stopper 749 is coupled to the lower periphery of the electric pulley 746 and rotates together with the electric pulley 746 to lower the lower end of the spacer 743 among the spacers 743 stored in the cartridge 742. The second drop space 750 is formed to support and drop the spacer 743 at the lowermost side every time the electric pulley 746 is rotated once.

The first stopper 747 is coupled to the upper periphery of the electric pulley 746, rotated with the electric pulley 746, and the bottom of the second spacer 743 from the lower side among the spacers 743 housed in the cartridge 742. The first drop space 748 is formed so that the second spacer 743 is dropped from the lower side and supported by the second stopper 749 each time the electric pulley 746 is rotated once.

The adiabatic block turning unit 800 holds the adiabatic blocks 10 stacked in the lamination space and turns the coated surface to which the mixed solution is applied to face the adiabatic block 10 attachment surface of the cargo hold.

The adiabatic block turning part 800 is a turning part fixing frame 801 and a turning part fixing frame 801 in which the insulating block 10 installed and stacked on the conveying conveyor part 900 are located, and the turning part is fixed to the turning part 801. The turning drive pulley, which is connected to the turning drive motor 803 installed on the auxiliary fixing bracket 802, the turning part fixing bracket 802, and the turning driving motor 803, transmits rotational power from the turning driving motor 803. 804, a rotating shaft 807 which is installed to rotate on the turning part fixing bracket 802, and a turning coupled to one end of the rotating shaft 807 and transmitting the rotational power of the turning drive motor 803 to the rotating shaft 807. A turning drive belt 805 connected to the electric pulley 806, the turning drive pulley 804, and the turning electric pulley 806 to transmit the rotational force of the turning drive pulley 804 to the turning electric pulley 806, and a rotating shaft Clamp connection bracket 808 fixed to the other end of (807) and rotated together with the rotating shaft (807), clamp connection bracket (808) Clamp actuating cylinders 809 which are respectively installed at both ends of the rotating shaft 807 and are rotated together with the clamp connecting bracket 808 when the rotating shaft 807 rotates, and are connected to the clamp actuating cylinder 809 to insulate the actuation of the clamp actuating cylinder 809. It is made of a clamp 810 to grip the side of the insulating block 10 while being transferred to the block 10 side.

The liquid-liquid mixing device for ship cargo insulation block of the present invention having such a configuration is operated as follows.

First, while the air lifter cylinder 120 and the motor 150 are operated, the main agent of the main drum 101 and the hardener of the hardener drum 201 are pressed toward the center of the material guide surface 131 of the follower plate 130.

When the air lifter cylinder 120 is operated so that the upper frame 122 descends, the follower plate 130 descends and presses the main subject in the main drum 101. Accordingly, the main subject is transported along the raw material guide surface 131 while the main frame is lowered. It is supplied to the charge block 134.

In addition, when the motor 150 is driven, the motor shaft 151 rotates the gear pump shaft 141 so that the gear pump 140 is driven. When the gear pump 140 is driven, a suction force is generated in the follower plate 130, and thus the main body in the main drum 101 is supplied to the discharge block 134. Thus, the subject is supplied to the discharge block 134 while being pressed by the air lifter cylinder 120 and sucked by the gear pump 140.

 The main body supplied to the discharge block 134 compresses the pressure spring 166 by pushing the non-return valve 165 of the non-return valve 160 so that the inlet 163, the flow path 162, Via the outlet 164 is supplied to the heating hose 168. The main body supplied to the heating hose 168 flows into the non-return valve 401 of the injection unit 400.

Since the curing agent part 200 also has the same configuration as the main part 100, it is supplied to the non-return valve 401 of the injection part 400 in the same manner as the main part. The main body and the hardener supplied to the non-return valve 401 are first mixed while being supplied to the mixing block 403 by the driving cylinder 405 and then supplied to the mixing tube 407. The release mixture supplied to the mixing tube 407 is secondly mixed by the stick mixer 408 and then sprayed through the nozzle 409.

On the other hand, when the insulating block 10 is located below the pickup 500, the pickup lift cylinder 540 is operated to lower the vacuum pad 570, the vacuum pad 570 is the upper surface of the insulating block 10 When it comes in contact with the vacuum pump 560 is driven so that the vacuum pad 570 is adsorbed to the insulating block 10.

When the adiabatic block 10 is adsorbed on the vacuum pad 570, the pick-up lift cylinder 540 is operated to raise the adiabatic block 10, and the horizontal transfer cylinder 530 is operated to transfer the adiabatic block 10 to the X-axis. Place on conveyor 910. When the adiabatic block 10 is positioned on the X-axis transfer conveyor 910, the pickup lift cylinder 540 is operated to seat the adiabatic block 10 on the X-axis transfer conveyor 910, and in the vacuum pad 570. The vacuum is released.

The insulating block 10 seated on the X-axis conveying conveyor 910 is transferred to the cleaning unit 600, and the air is injected from the cleaning nozzle 602 of the cleaning unit 600 while the insulating block to which the release mixture is applied. The application surface of (10) is washed.

The insulating block 10 passing through the cleaning part 600 is transferred to the spraying part 400 side, and the spraying part 400 applies the release mixture to the application surface of the insulating block 10 to have a predetermined pattern.

The injection unit 400 is provided with means for transferring the nozzle 409 in the X-axis direction, the Y-axis direction, and the Z-axis direction. Therefore, the nozzle 409 of the injection unit 400 moves in the X-axis, Y-axis, and Z-axis directions to apply a release mixture solution to have a predetermined pattern on the coated surface of the insulating block 10.

 When the release mixture is applied to the coated surface of the insulating block 10, the insulating block 10 is moved from the X-axis transfer conveyor to the turning conveyor 930. When the adiabatic block 10 is positioned above the turning conveyor 930, the angle adjustment cylinder 936 is driven to hinge the Y-axis feed roller angle cutting bracket 933 and the Y-axis feed rollers 935 arranged thereon. Rotate to the upper direction centering on). Therefore, the insulating block 10 located above the turning conveyor 930 is transferred to the Y-axis transfer conveyor 920 along the inclined surface.

When the adiabatic block 10 is transferred to the Y-axis transfer conveyor 920, the adiabatic block stack 700 is operated to transport the adiabatic block 10 on the Y-axis transfer conveyor 920 to the loading space.

When the gripper 721 grips both sides of the insulating block 10 and loads it in the loading space, a plurality of spacers 743 are arranged on the upper surface of the insulating block 10 by the spacer supply part 740. The spacer 743 may be disposed at four corner portions to which the release mixture is not applied, and the spacer is supplied as follows.

When the spacer supply motor 741 is driven, the driving pulley 744 and the electric pulley 746 are interlocked, and the first stopper 747 and the second stopper 749 installed in the electric pulley 746 are rotated. The first space 748 and the second space 750 are formed in the first spacer 743 and the second spacer 743. Accordingly, the lower end of the spacer 743 is supported by the first stopper 747 and the second stopper 749, and the spacer 743 is rotated while the first stopper 747 and the second stopper 749 are rotated by one. When the lower end of the first falling space 748 and the second falling space 750 is located, the spacers 743 are dropped to the lower side.

At this time, the spacer 743 at the lowermost side is dropped to the lower side of the second drop space 750 of the second stopper 749 and is seated on the upper surface of the insulating block 10, and the spacer 743 positioned second from the bottom is made of the second spacer 743. Since the second stopper 749 is rotated 360 ° while passing through the first dropping space 748 of the first stopper 747, the second stopper 749 does not pass through the second dropping space 750 of the second stopper 749. 749 is supported.

When the spacers 743 are seated on the insulating block 10 loaded in the loading space, the insulating block stacking part 700 is driven to load another insulating block 10 for the purpose.

The liquid-liquid mixing device for a ship cargo insulation block of the present invention as described above has the following advantages.

First, when the main drum 101 seated on the auxiliary seating portion 117 is pushed toward the lower base frame 110, the feed roller 118 is idling and the main drum 101 of the weight is transferred to the lower base frame 110 side. The lower base frame 110 is transferred to the upper base frame 110 along the drum guide bar 111 and is seated on the drum fixing plate 112. Therefore, the operator can simply slide the main drum 101 of the weight to be seated on the lower base frame 110, the stable state because it is not moved by the drum fixing plate 112 in a state seated on the lower base frame 110 You can do this from.

Secondly, the heating unit 300 of the present invention includes a first heating unit 301 and a second heating unit 304 to be detached from the outer circumferential surface of the main drum 101. The outer circumferential length of the main drum 101 is longer than the sum of the circumferential length of the inner circumferential surface of the first heating unit 301 and the circumferential length of the inner circumferential surface of the second heating unit 304 and the length of the tension coil spring 310, When the first heating unit 301 and the second heating unit 304 are fastened to the outer circumferential surface of the main drum 101 with the detachable lever 308, the tension coil spring 310 is tensioned and the first heating unit 301 is engaged. And a second heating part 304 is elastically in close contact with the outer circumferential surface of the main drum 101. Therefore, since the heating unit 300 is fastened around the main drum 101, the inside of the main drum 101 can be uniformly heated, and the detachment of the heating unit 300 is very simple, thus maintaining the heating unit 300. It is very easy to repair, and when the heating unit 300 is mounted on the main drum 101 elastically close to the outer circumferential surface of the main drum 101 by the tension coil spring 310, the heat of the heating unit 300 The main drum 101 is stably transmitted.

Third, viscous fluid guide grooves 135 are formed on the material guide surface 131 of the follower plate 130. The viscous fluid guide grooves 135 are radially formed on the raw material guide surface 131 along the direction in which the viscous fluid flows when the viscous fluid is pressurized, and the cross section of the viscous fluid guide groove 135 has a semicircular shape. Therefore, when the viscous fluid is pressurized, a portion of the viscous fluid is guided to the outlet side of the follower plate 130 along the viscous fluid guide groove 135, so that the pressurized viscous fluid is transferred to the outlet side of the follower plate 130. Since the guide, the viscous fluid is guided to smoothly discharge along the raw material guide surface (131). A frictional force reducing coating layer may be applied to the viscous fluid guide groove 135. Therefore, when the follower plate 130 is pressurized, the topic entered into the viscous fluid guide groove 135 flows faster than the topic located outside the viscous fluid guide groove 135, thereby guiding the topic to be discharged quickly.

Fourth, the lower base frame 110 is further provided with a lifting unit 113 to elevate the drum fixing plate 112. Therefore, when the main drum 101 is moved to the lower base frame 110, the drum fixing plate 112 remains in a lowered state while the main drum 101 is seated on the lower base frame 110. 113 is driven to raise the drum fixing plate 112 to be seated on the lower step 101a of the main drum 101. Therefore, the main drum 101 seated on the lower base frame 110 is firmly supported.

Meanwhile, the metal mesh foam may be attached to the outer surface of the motor 150. The metal mesh foam is a metal mesh foam having pores.

The thermochromic layer is applied to the surface of the metal mesh foam and is configured to penetrate the surface of the metal mesh foam.

When the temperature change layer is above a predetermined temperature, two or more temperature change materials, which change color, are coated on the surface of the metal mesh foam and separated into two or more sections according to temperature change, thereby determining a stepwise temperature change. On the thermochromic layer, a protective layer may be applied to prevent the thermochromic layer from being damaged.

Here, the temperature change layer may be formed by applying a temperature change material having a color change temperature of 40 ° C. or higher and 60 ° C. or higher, respectively. The color change layer is for detecting the temperature change of the heater motor 150 by changing the color according to the temperature of the motor 150 which is indirectly heated as the temperature rises inside the heater. The temperature of the motor 150 is transmitted to the metal mesh foam, and the color change layer 162 reacts according to the temperature change of the metal mesh foam, and as a result, the temperature change of the motor 150 can be detected.

The thermochromic layer may be formed by applying a thermochromic material that changes color when a temperature is higher than a predetermined temperature to the surface of the metal mesh foam. In addition, the thermochromic layer is generally composed of a microcapsule structure of 1 ~ 10㎛, it can be colored and transparent due to the binding and separation phenomenon depending on the temperature of the electron donor and the electron acceptor in the microcapsules.

In addition, the color change layer has a rapid color change, and may have various color change temperatures such as 40 ° C., 60 ° C., 70 ° C., 80 ° C., and the like. The color change temperature can be easily adjusted in various ways. The thermochromic layer may be various kinds of thermochromic materials based on principles such as molecular rearrangement of organic compounds and rearrangement of atomic groups.

To this end, the thermochromic layer is preferably formed so that two or more thermochromic materials having different discoloration temperatures are separated into two or more sections according to temperature changes. The temperature discoloration layer is preferably a temperature discoloration material having a relatively low temperature discoloration temperature and a temperature discoloration material having a relatively high temperature discoloration temperature, more preferably having a discoloration temperature of 40 ° C. or higher and 60 ° C. or higher. The thermochromic material may be used to form a thermochromic layer.

Through this, the temperature change of the motor 150 can be checked, so that the temperature change of the motor 150 can be detected. Accordingly, it is easy to check whether the current motor 150 is normally driven or overheated. There is an advantage to this.

In addition, the protective film layer is applied on the temperature change layer to prevent the temperature change layer from being damaged by an external impact, and it is easy to check whether the temperature change layer is discolored, and at the same time, considering that the temperature change material is weak to heat, it has an insulating effect. It is preferable to use the transparent coating material which has a branch.

In addition, a frictional force reducing coating layer may be applied to the viscous fluid guide groove 135 of the raw material guide surface 131. The coating material of the frictional force reducing coating layer is 20% by weight of guanadino benzoimidazole and 15% of oxycarboxylic acid leaf. %, 10% by weight of imidazoline thione, 15% by weight of hafnium, 10% by weight of molybdenum emulsion (MoS2), 25% by weight of aluminum oxide, 5% by weight of diglycidyl aniline, the coating thickness of 7㎛ Can be.

Guanadino benzoimidazole, oxycarboxylic acid leaf, imidazoline thione, and diglycidyl aniline serve as corrosion protection and discoloration prevention.

Hafnium is a corrosion-resistant transition metal element that serves to have excellent waterproofness and corrosion resistance.

Molybdenum emulsion plays a role of imparting slidability and lubricity to the surface of the coating film.

Aluminum oxide is added for the purpose of fire resistance, chemical stability, and the like.

The reason for limiting the numerical value of the ratio and the coating thickness of the components as described above, the inventors analyzed through the test results several times, the ratio showed the effects of the optimum frictional force reduction and corrosion prevention at the ratio.

In addition, the raw material content ratio of the follower plate O-ring 132 may be made by mixing 60% by weight of rubber, 33 to 36% by weight of carbon black, 2 to 5% by weight of antioxidant, and 1 to 3% by weight of sulfur as an accelerator. .

Carbon black is added to increase the wear resistance, but if the content is less than 33% by weight, the elasticity and abrasion resistance is reduced, if the content exceeds 36% by weight, the rubber content of the main component is relatively small, there is a fear that the elastic force is lowered , 33 to 36% by weight.

Antioxidants add 2 to 5% by weight by selecting 3C (N-PHENYL-N'-ISOPROPYL-P-PHENYLENEDIAMINE) or RD (POLYMERIZED 2,2,4-TRIMETHYL-1,2-DIHYDROQUINOLINE) If it is less than the weight%, the product is easy to oxidize, and if it is added too much, if it exceeds 5 weight%, the rubber content of the main component is relatively small, and the elastic force may be reduced. ~ 5% by weight is appropriate.

Sulfur, an accelerator, is mixed with 1-3 wt%. Since less than 1% by weight of the vulcanization effect in the heating step during molding is minimal, 1% by weight or more is added. If it exceeds 3% by weight, the content of rubber, which is a main component, is relatively low, and there is a possibility that the elastic force may drop, so 1 to 3% by weight is appropriate.

Therefore, since the present invention is reinforced with synthetic rubber having elasticity in various directions, the elasticity, toughness, and rigidity of the follower plate O-ring 132 is increased, thereby improving durability, and thus, the life of the follower plate O-ring 132 is increased.

100: topic 101: topic drum
110: lower base frame 111: drum guide bar
112: drum fixing plate 113: lifting unit
114: caster 115: level foot
116: lifting bolt 117: auxiliary seat
118: feed roller 120: air lift cylinder
121,531,541: Cylinder rod 122: Upper frame
123: Rework Clip 130: Followers Plate
131: raw material guide surface 132: follower plate O-ring
133: distance rod 134: discharge block
135: viscous fluid guide groove 140: gear pump
141: gear pump shaft 142: gear pump coupling
144: motor fixing housing 150: motor
151: motor shaft 152: downcoupling
153: connection plate 160: non-return valve
161: valve body 162: flow path
163: entrance 164: exit
165: non-return valve 166: pressure spring
167: stopper 168: heating hose
170: air vent unit 171: degassing lever
172: supply line 200: hardener
201: curing agent drum 300: heating unit
301: first heating unit 302: first heating cover
303: first heater 304: second heating part
305: second heating cover 306: second heater
308: detachment lever 309: detachment
310: tension coil spring 400: injection part
401: non-return valve 402: rotary fitting
403: mixing block 404: heater
405: driving cylinder 406: terminal nipple
407: mixing tube 408: stick mixer
409 nozzle 500 pickup part
510: pickup frame 511: horizontal feed rail
520: horizontal feed frame 530: horizontal feed cylinder
532: rod fixing end 540: pickup lift cylinder
550: pad fixing plate 560: vacuum pump
570: vacuum pad 580: pickup guide
581 pickup guide bar 600 cleaning unit
601: air distribution pipe 602: cleaning nozzle
603: air supply hose 700: insulating block laminated portion
701: laminated part frame 702: laminated part horizontal transfer rail
703: horizontal transfer plate laminated 704: laminated lifting drive motor
705,731,744: Drive pulley 706: Guide pulley
707: lifting belt 710: gripper mounting plate
711: guide rod guide 712: installation plate lifting guide rod
720: gripper horizontal transfer rail 721: gripper
722: fixing bracket 723: gripper operation cylinder
724: cylinder cylinder 730: horizontal drive motor
732: driving timing pulley 733: driving belt
734: electric timing pulley 735: timing belt
740: spacer supply unit 741: spacer supply motor
742: cartridge 743: spacer
745: electric belt 746: electric pulley
747: first stopper 748: first falling space
749: second stopper 750: second falling space
751: supply plate 800: heat insulation block turning
801: turning part fixing frame 802: turning part fixing bracket
803: turning drive motor 804: turning drive pulley
805: turning electric belt 806: turning electric pulley
807: rotating shaft 808: clamp connection bracket
809: clamp operating cylinder 801: clamp
900: conveying conveyor 910: X-axis conveying conveyor
920: Y-axis feed conveyor 930: Turning conveyor
931: Turning Conveyor Frame 932: X-axis Feed Roller
933: Y-axis feed roller angle adjusting bracket
934: hinge shaft 935: Y-axis feed roller
936: angle adjustment cylinder

Claims (3)

The main body is stored therein and is provided with a main drum 101 having a step 101a formed at the lower end, a lower base frame 110 on which the main drum 101 is seated, and one side of the lower base frame 110. Auxiliary seating portion 117, which is a cost-based drum is seated, the air lifter cylinder 120 is installed on the lower base frame 110, and the upper frame coupled to the top of the cylinder rod 121 of the air lifter cylinder 120 ( 122 and a follower plate 130 coupled to the upper frame 122 to press down the inside of the main drum 101 while being lowered during operation of the air lift cylinder 120, and installed on the upper surface of the follower plate 130. The discharge block 134 and the discharge block 134 for guiding the main body pressurized by the follower plate 130 to discharge the injection unit 400 side through the supply line 172 are disposed on the discharge block 134 and discharged. Allow vacuum suction force to be formed inside the block 134. The main part 100 consisting of a gear pump 140;
A curing agent part 200 to which the curing agent drum 201 is seated and pressurizes the inside of the curing agent drum 201 to supply a curing agent inside the curing agent drum 201;
A heating part 300 coupled to the main drum 101 of the main part 100 and the curing agent drum 201 of the hardener part 200 to heat the main part and the hardener;
The injection part 400 connected to the main part 100 and the hardener part 200 to mix the main part and the hardener supplied from the main part 100 and the hardener part 200 and apply the mixed mixture to the insulating block 10. ) Is provided;
The heating unit 300,
The first heating unit 301 and the first heating unit 301 comprising a first heater 303 surrounding a part of the outer peripheral surface of the main drum 101 and a first heating cover 302 surrounding the first heater 303. A second heating unit 304 formed of a second heater 306 which surrounds a part of the outer circumferential surface of the main drum 101, and a second heating cover 305 which surrounds the second heater 306, and a first pair The tension coil spring 310 connected to the corresponding ends of the heating unit 301 and the second heating unit 304, the detachable piece 309 provided in the first heating unit 301, and the second heating unit ( And a detachable lever 308 attached to and detached from the detachable piece 309 so that the heating part 300 is detachably attached to the outer circumferential surface of the main drum 101;
The outer circumferential length of the main drum 101 is longer than the sum of the circumferential length of the inner circumferential surface of the first heating unit 301 and the circumferential length of the inner circumferential surface of the second heating unit 304 and the length of the tension coil spring 310, When the heating unit 301 and the second heating unit 304 are fastened to the outer circumferential surface of the main drum 101 by the detachable lever 308, the first coil 301 and the first heating unit 301 are tensioned while the tension coil spring 310 is tensioned. 2 heating unit 304 is a liquid-liquid mixing device for a cargo hold insulation block, characterized in that it is provided so as to be elastically in close contact with the outer peripheral surface of the main drum (101).
The method according to claim 1, wherein the raw material guide surface 131,
Viscous fluid guide grooves 135 are formed, and the viscous fluid guide grooves 135 are formed radially on the raw material guide surface 131 along the direction in which the viscous fluid flows when the viscous fluid is pressurized, and the viscous fluid guide groove 135 is formed. The cross section of is in the form of semicircle,
When the viscous fluid is pressurized, a part of the viscous fluid is guided to the outlet side of the follower plate 130 along the viscous fluid guide groove 135 so that the pressurized viscous fluid is guided to the exit side of the follower plate 130. Equipped,
Viscous fluid guide groove 135 is a liquid-liquid mixing device for a ship cargo insulation block, characterized in that the frictional force reducing coating layer is applied.
The method according to claim 1,
When the main drum 101 is seated on the lower base frame 110, the lower base frame 110 is mounted on the lower step 101a of the main drum 101 to prevent the main drum 101 from flowing. The fixing plate 112 is provided,
An elevating part 113 is provided between the lower base frame 110 and the drum fixing plate 112 to elevate the drum fixing plate 112, and the main drum 101 is transferred to the upper side of the lower base frame 110. When the drum fixing plate 112 is positioned lower than the lower end of the main drum 101 and the main drum 101 is seated on the lower base frame 110, the drum fixing plate 112 is raised to The lyotropic liquid mixing apparatus for ship cargo insulation block, characterized in that it is provided to be seated on the lower step (101a) of the drum (101).

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