KR100937155B1 - Heater for liquified gas supplying apparatus - Google Patents

Abstract

PURPOSE: A heater for a liquefied gas supply device is provided to improve heating performance by closely adhering the heater to a surface of a storage tank. CONSTITUTION: An induction coil(220) is included in a casing. A magnet(230) is detachably attached to a surface of a storage tank of the liquefied gas supply device with the magnetic force. The magnet is an electromagnet embedded in the casing. A handle(250) includes a switching unit and grasps the heater. The switching unit supplies or blocks the current to the electromagnetic coil.

Description

Liquefied gas supply heating heater {HEATER FOR LIQUIFIED GAS SUPPLYING APPARATUS}

The present invention relates to a liquefied gas supply device heating heater, and more particularly, to a liquefied gas supply device heating heater, which is composed of a magnet type and easily detachable to and from the storage tank of the liquefied gas supply device.

Usually, in the manufacture of semiconductors, LCDs, LEDs, and cells, gases such as NH 3, HBr, HCl, and the like are used as process gases. This process gas is filled and stored in a large storage tank in a liquefied state, and is heated and vaporized by a heater and supplied to each process use place.

1 is a schematic diagram of a conventional liquefied gas supply device. As shown, the process gas is stored in the liquefied state in two adjacent storage tanks 10 and 10 ', and is stored in the storage tanks 10 and 10' by heating the surfaces of the storage tanks 10 and 10 '. As the liquefied gas is vaporized it is supplied to the process site. Since the process gas must be continuously supplied to the process user in real time, the capacity of the storage tanks 10 and 10 'is very large, and thus the replacement work for refilling gas after use is very cumbersome. Therefore, in actual practice, as the two large storage tanks are disposed adjacent to each other, the replacement cycle of the storage tanks 10 and 10 'is extended, and the adjacent storage tanks 10 and 10' are simultaneously replaced after gas consumption. I'm taking the way.

Thus, in order to transfer the process gas vaporized and discharged from two adjacent storage tanks 10 and 10 'to each process use place, as shown in FIG. 1, each storage tank 10 and 10' has a discharge pipe. 40 and 40 'are connected and vaporized process gas is discharged through the discharge pipes 40 and 40'. The discharge pipes 40, 40 'are converged into one transfer pipe 50, and the transfer pipe 50 is connected to a process destination. That is, the process gas vaporized from each of the storage tanks 10 and 10 'is independently discharged through the discharge pipes 40 and 40' and then combined in one transfer pipe 50 to be supplied to the process user. On the other hand, each of the storage tank (10, 10 ') is coupled to the hood box (30, 30') having a built-in power supply and equipped with exhaust pipes (31, 31 ') exhaust pipe 31, 31' It is configured to be discharged to the outside through. In addition, in order to facilitate the movement of the storage tank (10, 10 ') of replacement, below the storage tank (10, 10') is provided with a moving trolley (60, 60 ') with a wheel.

Meanwhile, in order to vaporize the liquefied gas, a heater for heating each of the storage tanks 10 and 10 'must be provided. As shown in FIG. 1, a jacket heater 20 and 20' is used. The jacket heater (20, 20 ') is a mat-type heater with a heating wire therein is fixed by a belt in the state covering the outer peripheral surface of the cylindrical storage tank (10, 10') storage tank (10, 10) ') Is configured to heat the surface and is called a jacket heater because it is coated on the storage tanks 10, 10' like a jacket.

However, according to such a jacket heater, when the gas is consumed and the storage tanks 10 and 10 'are to be replaced, the heater must be peeled off and a newly charged storage tank must be installed before the heater is re-applied. Since the jacket heater's volume is very large and the weight is about 40kg, it is not only possible to replace the heater alone, but also because the heater is drooping downward due to its own load, the heater cannot be adhered to the surface of the storage tank. Existed.

The present invention was devised to solve the problems of the conventional liquefied gas supply heater for heating as described above, the removable heater is easily attached and detached, the heating heater is in close contact with the storage tank can be carried out smooth heating operation An object of the present invention is to provide a liquefied gas supply heating heater.

The objects and advantages of the present invention will be described in more detail below, and will be further embodied by the examples. Furthermore, the objects and advantages of the present invention can be realized by the means indicated in the claims and combinations thereof.

The liquefied gas supply device heating heater according to the present invention for achieving the above object, the casing; An induction coil provided in the casing; A magnet detachably attaching the heating heater to the storage tank surface by a magnetic force; And a handle for holding the heating heater.

Here, the magnet is preferably a rubber magnet attached to the lower portion of the casing, or an electromagnet embedded in the casing.

When the magnet is an electromagnet, the handle is further provided with switching means for supplying and blocking current to the electromagnet coil.

The switching means may include a switching lever horizontally installed inside the handle of the heating heater and vertically movable along a long groove formed inside the vertical part of the handle; A support protrusion protruding upward from an end of the switching lever; An elastic spring whose one end is supported on the inner upper surface of the horizontal portion of the handle and the other end is elastically supported by the support protrusion; A fixed contact point formed at both left and right sides of the inner bottom surface of the handle, one of which is connected to an external power source, and the other of which is connected to an electromagnet coil; It is installed through the support protrusion in the horizontal direction, and moves together with the vertical movement of the switching lever includes a movable contact on and off the fixed contact.

On the other hand, the switching means may be a pushbutton switch.

In addition, the lower surface of the casing is preferably attached to a buffer pad made of silicon to prevent the heating heater from being damaged by a collision with the storage tank.

According to the present invention as described above, it is easy to replace and detach the heating heater to the storage tank is easy to replace, because the heating heater is in close contact with the surface of the storage tank is excellent in heating performance, because the heating heater is composed of an induction heating heater It has an excellent effect of easy temperature control.

Hereinafter, the specific configuration of the liquefied gas supply heating heater according to the present invention will be described in detail with reference to the preferred embodiments and the accompanying drawings.

2 is a block diagram of a heating heater according to a preferred embodiment of the present invention, Figure 3 is a block diagram of a heating heater according to another embodiment of the present invention, Figure 4 is an electromagnet of the heating heater A structural detail diagram of the switching means for operation is shown, and FIG. 5 shows a structural detail of the switching means according to another embodiment of the present invention.

The heating heater 200 is attached to the surface of each of the storage tanks 10 and 10 ', respectively, to heat each of the storage tanks 10 and 10', and is an induction heating type heater. Induction heating refers to a phenomenon in which a eddy current is generated in a conductor adjacent to a coil by an electromagnetic induction phenomenon as the current flows through the coil, and the conductor is heated by Joule's heat generated by the eddy current.

As shown in FIG. 2, the heating heater 200 according to a preferred embodiment of the present invention includes a casing 210, an induction coil 220, a magnet 230, and a handle 250.

The casing 210 has a predetermined receiving space therein, and is generally a flat rectangular parallelepiped enclosure made of Teflon material, and an induction coil 220 and a heater built-in temperature sensor 240 are provided therein.

The induction coil 220 forms a magnetic field around the current supply, and is disposed in a state of being wound a plurality of times while drawing a concentric circle inside the casing 210.

The heater built-in temperature sensor 240 senses the heating temperature according to the operation of the induction coil 220. The detected signal is transmitted to the control unit (not shown) as an electric signal, and the control unit compares the power with a predetermined preset temperature, controls the inverter (not shown) based on the comparison result, and supplies the power to the induction coil 220. Adjust the heating temperature by adjusting the frequency.

The casing 210 is provided with a connector 260 to connect a cable for supplying current to the induction coil 220 and a cable for a heater built-in temperature sensor.

The magnet 230 is to detachably attach the heating heater 200 to the metal storage tanks 10 and 10 'by magnetic force, and is firmly attached to the lower portion of the casing 210 by an adhesive or the like. . As shown in FIG. 2, the lower surface of the magnet 230 is curved concave to correspond to the curvature of the outer circumferential surface of the storage tanks 10 and 10 'so as to be closely attached to the storage tanks 10 and 10'. It is preferably formed. In addition, the magnet 230 may be easily bonded to the casing 210, and a rubber magnet may be used to achieve a buffering effect for preventing the storage tanks 10 and 10 ′ from being damaged by an impact. Do.

In addition, the handle 250 is preferably formed on the upper surface of the outer casing 210 so that the operator can easily grip.

Through this configuration, the operator attaches the heating heater 200 to the outer circumferential surface of the storage tanks 10 and 10 'while holding the handle 250 and applies a current to the induction coil 220, thereby storing the tank. The (10, 10 ') surface can be heated to vaporize the liquefied gas.

On the other hand, according to another preferred embodiment of the present invention, to facilitate the attachment and detachment of the heating heater 200, the electromagnet 270 may be used instead of the permanent magnet. 3 shows a schematic diagram of a heating heater using an electromagnet 270.

As shown in FIG. 3, the heating heater 200 using the electromagnet 270 is provided with an electromagnet 270 inside the casing 210. The electromagnet 270 is composed of an iron core, which is a conductor, and a coil wound around the outside of the iron core, and as shown in FIG. 3, the electromagnet 270 is preferably provided one by one on both left and right sides of the casing 210. The electromagnet 270 is configured to be magnetic when a current is applied to the coil and to lose magnetic when the current is stopped. The application of current to the coil is performed through the connector 260 provided in the casing 210.

As such, in the present embodiment, since the electromagnet 270 is attached to the surface of the storage tanks 10 and 10 ', a separate rubber magnet does not need to be provided under the casing 210, and instead of the rubber magnet, the storage tank ( 10, 10 ') It is preferable to attach a buffer pad 280 made of silicon to prevent surface damage.

On the other hand, the application of the current to the electromagnet 270 may be performed by the on and off of the external power source, in the present embodiment, for the convenience of the user, the power supply to the handle 250 of the heating heater 200 by an electromagnet coil. It is preferable that the switching means 300 for supplying and blocking are additionally provided. 3 is an external perspective view of a heating heater 200 having such a switching means 300, and FIG. 4 shows a contact structure of the switching means 300.

As shown in FIGS. 3 and 4, the switching means 300 includes a switching lever 310, an elastic spring 330, a fixed contact 340, and a movable contact 350.

The switching lever 310 is configured in the shape of a rod or rod, and is horizontally installed inside the handle 250 formed on the casing 210 surface, so that the user pulls the handle 250 upward with the finger. While moving, the application of current to the coil is stopped, and when released, the member returns to its original position and the current is applied to the coil.

In order to vertically move the switching lever 310, a long groove 252 is formed inside the vertical portion of the handle 250 so that the switching lever 310 can be moved up and down in the state where the end of the switching lever 310 is inserted. An elastic spring 330 is installed inside the horizontal end of the handle 250 to return the switching lever 310 moved upward. One end of the elastic spring 330 is supported on the inner upper surface of the horizontal portion of the handle 250, the other end is formed as a support projection 320 protruding upward at the end of the switching lever 310 as shown in FIG. Is elastically supported.

In addition, two fixed contacts 340 are formed on both left and right sides of the inner bottom of the horizontal portion of the handle 250 to apply and cut off current to the electromagnet coil as the switching lever 310 moves up and down. One of the fixed contacts 340 is electrically connected by a connector and an electric wire connected to an external power source, and the other contact is connected to the coil of the electromagnet 270.

On the other hand, as shown in Figure 4, the movable contact 350 is installed in the horizontal direction through the upper portion of the support protrusion 320 provided at the end of the switching lever 310. The movable contact 350 moves together when the switching lever 310 moves up and down to simultaneously apply and drop the two fixed contacts 340 to apply or cut off current to the electromagnetic coil.

Through this configuration, when the power cable is connected to the first connector, the switching lever 310 is moved downward by the elastic spring 330, and thus the movable contact 350 is also moved downward to Since it is attached to the fixed contact 340, a current is applied to the electromagnet coil, the electromagnet 270 is magnetic. Since the electromagnet 270 is magnetic, the user can easily attach the heating heater 200 to the storage tanks 10 and 10 ′.

On the other hand, when the heating heater 200 is to be replaced, when the user pulls the switching lever 310 upward with a finger while holding the handle 250 of the heating heater 200, the elastic spring 330 contracts. As the switching lever 310 rises, and thus, the movable contact 350 also rises and falls from the fixed contact 340. Since the movable contact 350 is separated from the fixed contact 340, the current is no longer applied to the electromagnet coil and the electromagnet 270 loses its magnetism, so that the heating heater 200 is easily detached from the storage tanks 10 and 10 '. Will be.

In this way, the switching means 300 may be configured as a switching lever 310 of the auxiliary handle form, as shown in Figure 6, a general push-button switch 360 or a sliding switch for power on or off is used It may be fine.

So far, the present invention has been described with reference to the embodiments, but the scope of the present invention is not limited thereto, and the scope of the present invention is substantially equivalent to the embodiments.

1 is a configuration diagram of a conventional liquefied gas supply device,

2 is a block diagram of a heating heater according to an embodiment of the present invention;

3 is a configuration diagram of a heating heater according to another embodiment of the present invention;

4 is a structural diagram of a switching means for operating an electromagnet of the heating heater;

5 is a structural diagram of a switching means according to another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10,10 ': Storage tank 20,20': Jacket heater 30,30 ': Hood box 40,40': Discharge tube

50: transfer pipe 60,60 ': trolley 200: heating heater 210: casing

220: induction coil 230: magnet

240: heater built-in temperature sensor 250: handle

252: long groove 260: connector

270: electromagnet 280: buffer pad

300: switching means 310: switching lever

320: support protrusion 330: elastic spring

340: fixed contact 350: movable contact

360: pushbutton switch

Claims (7)

Liquefied gas supply heating heater, Casing; An induction coil provided in the casing; A magnet detachably attaching the heating heater to the storage tank surface of the liquefied gas supply device by a magnetic force; Including a handle for holding the heating heater, The magnet is an electromagnet embedded in the casing, The handle is further provided with a switching means for supplying and blocking current to the electromagnet coil, The switching means may include: a switching lever horizontally installed inside the handle and movable up and down along a long groove formed inside the vertical part of the handle; A support protrusion protruding upward from an end of the switching lever; An elastic spring whose one end is supported on the inner upper surface of the horizontal portion of the handle and the other end is elastically supported by the support protrusion; A fixed contact point formed at both left and right sides of the inner bottom surface of the handle, one of which is connected to an external power source, and the other of which is connected to an electromagnet coil; The liquefied gas storage tank heating heater, characterized in that it comprises a movable contact penetrates the support protrusion in the horizontal direction and moves together with the vertical movement of the switching lever to turn on and off the fixed contact point. delete delete delete delete Liquefied gas supply heating heater, Casing; An induction coil provided in the casing; A magnet detachably attaching the heating heater to the storage tank surface of the liquefied gas supply device by a magnetic force; Including a handle for holding the heating heater, The magnet is an electromagnet embedded in the casing, The handle is further provided with switching means for supplying and blocking current to the electromagnetic coil, the switching means is a liquefied gas storage tank heating heater, characterized in that the pushbutton switch. The method according to claim 1 or 6, Liquefied gas storage tank heating heater, characterized in that a buffer pad of silicon material is attached to the lower surface of the casing to prevent the heating heater from being damaged by a collision with the storage tank.

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