KR20210031363A - Heating Device for Liquefied Gas Cylinder - Google Patents

Abstract

The present invention provides an apparatus for heating a liquefied gas bomb, in which an induction coil is formed in a curved shape and has variable length to be in close contact with the liquefied gas bomb and positioned at a uniform interval, such that the liquefied gas is quickly and evenly vaporized, and the temperature of the liquefied gas bomb is sensed and controlled such that the vaporization of a constant amount of liquefied gas can be maintained at all times. The apparatus for heating the liquefied gas bomb in accordance with the present invention comprises: a heating plate having an induction coil therein formed in a curved shape corresponding to a circular arc surface; an assembly support plate on which the heating plate is installed and supported; a base plate on which the assembly support plate is mounted and supported; a contact-type temperature sensor installed on the heating plate and measuring the temperature of the heating plate; a non-contact-type temperature sensor installed on the base plate or the heating plate and measuring the temperature of the liquefied gas bomb in contact with the heating plate; and a controller configured to control the operation of the induction coil installed on the heating plate in response to the temperature of the heating plate and the liquefied gas bomb sensed by the contact-type temperature sensor and the non-contact-type temperature sensor.

Description

Liquefied Gas Cylinder Heating Device {Heating Device for Liquefied Gas Cylinder}

The present invention relates to a liquefied gas cylinder heating apparatus, and more particularly, to a liquefied gas cylinder heating apparatus capable of forming a shape corresponding to the diameter of the liquefied gas cylinder and adjusting its size and maintaining a constant temperature. will be.

In general, a reaction gas used in a process of manufacturing a display device such as a semiconductor, LCD or LED is stored as a liquefied gas.

Liquefied gas is stored in a state filled in a pressure container (bomb), and is transported to the required place along the gas pipe as it is vaporized and used.

In addition, in order to promote vaporization of the liquefied gas, a heating device is installed in a supply facility such as a pressure vessel (cylinder) or a gas pipe.

Korean Patent Publication Nos. 10-1603950, 10-1363976, 10-1094186, and 10-0990157 disclose technologies for various jacket-type heaters for heating a liquefied gas cylinder.

In the case of a conventional jacket type heater, there is a difficulty in manually tightening each time during installation and removal, and since AC power is applied, there is a risk of short circuit and short circuit due to wear or impact during installation and removal. There is a problem that the efficiency and heating rate are considerably lowered because the internal heating wire is installed in a zigzag manner.

In addition, in the case of a conventional jacket type heater, it is difficult to cope with the temperature change of the liquefied gas cylinder itself, because only the temperature of the heater is sensed to prevent and control overheating.

For example, when the valve of the liquefied gas cylinder is opened and the vaporized liquefied gas is supplied, a large amount is instantaneously discharged, so that the internal temperature of the liquefied gas cylinder is lowered and the vaporization rate of the liquefied gas is lowered. However, since the temperature sensor installed in the jacketed heater senses only the temperature of the heater, it is difficult to respond to increase the temperature of the liquefied gas cylinder by increasing the temperature of the heater.

In addition, when the amount of the liquefied gas filled in the liquefied gas cylinder is large and when the amount of the liquefied gas is small, a difference occurs in the amount of the liquefied gas vaporized even at the same temperature of the jacket heater.

The present invention is made by looking at the above points, and the induction coil is formed in a curved shape and its length is configured to be variable, so that it is in close contact with the liquefied gas cylinder and located at a uniform interval, so that the vaporization of the liquefied gas is made quickly and evenly. To provide a liquefied gas cylinder heating device capable of always maintaining a constant amount of liquefied gas vaporization because it senses and controls the temperature of the liquefied gas cylinder.

The liquefied gas cylinder heating apparatus according to an embodiment of the present invention includes a heating plate in which an induction coil formed in a curved shape corresponding to an arc surface is installed therein, an assembly support plate supported by installing the heating plate, and the assembly support plate. It is configured to control the operation of the supported base plate, the contact type temperature sensor installed on the heating plate and measuring the temperature of the heating plate, and the induction coil installed on the heating plate in response to the temperature of the heating plate detected by the contact type temperature sensor. It is made including a controller to be.

In addition, it is possible to further include a non-contact temperature sensor installed on the base plate or the heating plate and measuring the temperature of the liquefied gas cylinder in contact with the heating plate.

The controller is configured to dynamically control the operation of the induction coil installed on the heating plate in response to the temperature of the liquefied gas cylinder detected by the non-contact temperature sensor.

In the controller, it is possible to control the induction coil to operate when the measured value of the non-contact temperature sensor is below a set temperature, and control the induction coil to stop when the measured value of the non-contact temperature sensor exceeds a set temperature. Do.

In addition, it is possible to further include a non-contact auxiliary temperature sensor installed at a distance from the non-contact type temperature sensor installed on the base plate or the heating plate in order to measure the temperature of the part of the liquefied gas cylinder not in contact with the heating plate.

The controller may be configured to dynamically control whether or not the induction coil is operated by comparing the measured value of the auxiliary temperature sensor in the non-contact period with a set reference value.

In addition, it is also possible to install one or more object detection sensors on a surface of the base plate in contact with the liquefied gas cylinder to check whether the heating plate is installed in a state in which it is in contact with the liquefied gas cylinder.

The controller may be configured to operate the induction coil of the heating plate when the liquefied gas cylinder is installed in close contact with the heating plate in response to a detection signal from the object detection sensor.

It is also possible to install close contact straps for winding and fixing the liquefied gas cylinder at both outer corners of the base plate in the circumferential direction.

It is also possible to form the fixing structure of both ends of the adhesive strap by a Velcro method or a ratchet method so that the length of the adhesive strap can be freely adjusted and fixed.

The heating plate, the assembly support plate, and the base plate constitute one induction module.

The induction module may be coupled and installed on the inner surface of the rear plate of the cabinet in which the liquefied gas cylinder is stored.

It is also possible to install a loading table on which the liquefied gas cylinder is loaded on the upper surface of the bottom plate of the cabinet.

It is also possible to install a load cell sensor to detect the weight of the liquefied gas cylinder to be loaded on the loading table.

In the cabinet, it is also possible to install a fastening guide member on which the base plate is movably supported in a horizontal direction on the inner surface of the rear plate.

In the cabinet, it is also possible to further install a mounting plate on the rear plate to which the liquefied gas cylinder is in contact with the base plate to be supported.

In addition, the liquefied gas cylinder heating apparatus according to an embodiment of the present invention comprises a heating plate in which an induction coil formed in a curved shape corresponding to an arc surface is installed therein, an assembly support plate on which the heating plate is installed and supported, and the assembly support plate. A fastening guide member that supports and moves toward the liquefied gas cylinder, a non-contact temperature sensor installed on the assembly support plate and measuring the temperature of the liquefied gas cylinder in contact with the heating plate, and the induction coil when the measured value of the non-contact temperature sensor is below a set temperature. It is also possible to include a controller for controlling this operation and controlling the operation of the induction coil to be stopped when the measured value of the non-contact temperature sensor exceeds a set temperature.

The assembly support plate may be formed to have a variable length by moving in a state of being divided into both sides around the center along the circumferential direction of the liquefied gas cylinder.

The assembly support plate is provided with a fixing member movably coupled to the fastening guide member, and the heating plate installed on the fixing member to move in both directions along the circumferential direction of the liquefied gas cylinder and the induction coil installed therein. It comprises a pair of moving members.

In the above, it is also possible to install the adhesive straps on both outer corners of the circumferential direction of the moving member.

It is preferable that the fixing member and the movable member be formed of a deformable elastic material because it is possible to maintain a state in close contact with the outer circumferential surface of the liquefied gas cylinder.

In addition, the liquefied gas cylinder heating apparatus according to an embodiment of the present invention may further include a bottom plate on which the liquefied gas cylinder is loaded.

It is also possible to install a loading table on which the liquefied gas cylinder is loaded on the upper surface of the bottom plate.

It is also possible to install a load cell sensor to detect the weight of the liquefied gas cylinder to be loaded on the loading table.

It is also possible to install a variable support column on one side of the bottom plate, and install the fastening guide member to the variable support column so as to move upwardly.

The variable support column may be installed on the floor plate so as to move back and forth and rotate.

It is also possible to install a fixed support pillar at a corner adjacent to the edge where the variable support pillar is installed on the floor plate.

The fixed support column includes a column member fixedly installed on one side of the bottom plate, and a curved seating member installed on the column member and supported by contacting a part of the outer circumferential surface of the liquefied gas cylinder loaded on the loading table of the bottom plate. It is also possible to do so.

It is also possible to install two or more seating members vertically arranged at regular intervals.

In the above, it is also possible to configure two or more fixing support columns such that two or more liquefied gas cylinders are loaded on the bottom plate, and a plurality of coil support plates corresponding to each liquefied gas cylinder may be installed on the fastening guide member.

According to the liquefied gas cylinder heating apparatus according to an embodiment of the present invention, the induction coil and the heating plate are formed in a curved shape and a contact string is installed, so that the heating plate on which the induction coil is installed remains in close contact with the outer peripheral surface of the liquefied gas cylinder. It is possible, and not only the vaporization of the liquefied gas takes place quickly and evenly, but also takes place efficiently.

In addition, according to the heating device for a cylindrical liquefied gas supply facility according to an embodiment of the present invention, a load cell sensor is installed on the bottom plate to detect the weight of the liquefied gas cylinder, so that the replacement timing according to the consumption of the liquefied gas is accurately checked. It is possible, and it is possible to prevent the supply of liquefied gas from being interrupted through an alarm or warning light.

And, according to the liquefied gas cylinder heating apparatus according to an embodiment of the present invention, since the object detection sensor is installed on the base plate or the assembly support plate, it is possible to easily check whether the heating plate is in contact with the liquefied gas cylinder in the correct position.

According to the liquefied gas cylinder heating apparatus according to an embodiment of the present invention, it is possible to install the induction module movably on the fastening guide member, so that the position of the assembly support plate can be appropriately adjusted according to the size of the liquefied gas cylinder. And it is possible to adjust the position so that effective heating takes place.

In addition, according to the liquefied gas cylinder heating apparatus according to an embodiment of the present invention, since a non-contact temperature sensor is installed on the base plate or the assembly support plate to sense and control the temperature of the liquefied gas cylinder, the temperature of the liquefied gas cylinder is always constant. It is possible to maintain, and it is possible to constantly control the amount of the liquefied gas to be vaporized.

1 is a perspective view showing a liquefied gas cylinder heating apparatus according to a first embodiment of the present invention.
2 is a perspective view showing an example of an induction module in the liquefied gas cylinder heating apparatus according to the first embodiment of the present invention.
3 is a block diagram illustrating a control operation of a controller in the liquefied gas cylinder heating apparatus according to the first embodiment of the present invention.
4 is a perspective view showing another example of an induction module in the liquefied gas cylinder heating apparatus according to the first embodiment of the present invention.
5 is a perspective view showing an example in which an induction module is disposed in a position corresponding to the top and bottom of the liquefied gas cylinder at intervals and installed in the liquefied gas cylinder heating apparatus according to the first embodiment of the present invention.
6 is a perspective view showing a liquefied gas cylinder heating apparatus according to a second embodiment of the present invention.
7 is a perspective view showing a liquefied gas cylinder heating apparatus according to a third embodiment of the present invention.
8 is an exploded perspective view showing a liquefied gas cylinder heating apparatus according to a third embodiment of the present invention.
9 is an exploded perspective view showing another example of an assembly support plate in the liquefied gas cylinder heating apparatus according to the third embodiment of the present invention.
10 is a perspective view showing a liquefied gas cylinder heating apparatus according to a fourth embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present invention. However, this is not intended to limit the present invention to a specific embodiment, it should be understood to include all changes, equivalents, or substitutes included in the spirit and scope of the present invention.

The terms used in the present specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, processes, operations, components, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the possibility of addition or presence of elements or numbers, processes, operations, components, parts, or combinations thereof is not preliminarily excluded.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in the present application. Does not.

The term "MODULE" described herein refers to a unit that processes a specific function or operation, and may mean hardware or software, or a combination of hardware and software.

Terms or words used in the present specification and claims are not limited to their usual or dictionary meanings and should not be interpreted, and the inventor may appropriately define the concept of terms in order to describe his own invention in the best way. Based on the principle that there is, it should be interpreted as a meaning and concept consistent with the technical idea of the present invention. In addition, unless otherwise defined in the technical terms and scientific terms used, they have the meanings commonly understood by those of ordinary skill in the art to which this invention belongs, and the gist of the present invention in the following description and accompanying drawings. Descriptions of known functions and configurations that may be unnecessarily obscure will be omitted. The drawings introduced below are provided as examples in order to sufficiently convey the spirit of the present invention to those skilled in the art. Accordingly, the present invention is not limited to the drawings presented below and may be embodied in other forms. In addition, the same reference numbers throughout the specification indicate the same elements. It should be noted that the same components in the drawings are denoted by the same reference numerals wherever possible.

Next, a preferred embodiment of the liquefied gas cylinder heating apparatus according to the present invention will be described in detail with reference to the drawings.

The present invention can be implemented in various forms, and is not limited to the embodiments described below.

Hereinafter, in order to clearly describe the present invention, detailed descriptions of parts not closely related to the present invention are omitted, and the same or similar components are denoted by the same reference numerals throughout the description of the present invention, and repetitive descriptions are omitted. .

First, the liquefied gas cylinder heating apparatus according to the first embodiment of the present invention, as shown in Figs. 1 to 3, a heating plate 52, an assembly support plate 51, a base plate 53, and a contact type. It comprises a temperature sensor 81 and a controller 80.

The heating plate 52 is formed in a curved shape corresponding to an arc surface.

An induction coil is installed inside the heating plate 52 in a curved shape corresponding to an arc surface.

In addition, as shown in FIG. 4, two or more induction coils installed on the heating plate 52 may be connected in parallel to be installed.

In the case of installing a plurality of induction coils as described above, it is possible to secure a wide surface area to be heated, and the remaining induction coils operate even when a problem occurs in any one of the induction coils. It is possible to carry out heating.

If a plurality of induction coils are installed as described above, after replacing the liquefied gas cylinder (2), there is not enough waiting time to supply the liquefied gas and when the liquefied gas must be supplied immediately, when supplying the liquefied gas with a large amount of usage. Even if the temperature drops rapidly, it is possible to shorten the time for heating the liquefied gas cylinder 2 to the required temperature.

The heating plate 52 is installed and supported on the assembly support plate 51.

The heating plate 52 and the assembly support plate 51 are installed to be in close contact with and coupled to one of the outer circumferential surfaces of the liquefied gas cylinder 2.

The assembly support plate 51 is mounted and supported on the base plate 53.

The contact temperature sensor 81 is installed on the heating plate 52.

For example, the contact-type temperature sensor 81 may be disposed and installed in the center of the induction coil installed on the heating plate 52.

The contact-type temperature sensor 81 measures the temperature of the heating plate 52. Here, the temperature of the heating plate 52 reflects the actual temperature of the induction coil.

The controller 80 is configured to control the operation of the induction coil installed on the heating plate 52 in response to the temperature of the heating plate 52 sensed by the contact-type temperature sensor 81.

For example, the controller 80 stops the operation of the induction coil when the temperature of the heating plate 52 detected by the contact-type temperature sensor 81 exceeds a set upper limit reference value, and supplies power to the induction coil. In the applied state, when the temperature of the heating plate 52 is maintained below the set lower limit reference value, it is possible to determine that there is an abnormality in the induction coil, cut off the power, and then display a warning signal.

If configured as described above, it is possible to prevent the induction coil installed on the heating plate 52 from being damaged due to overheating, and to detect and respond to an abnormality in a short time.

In addition, the liquefied gas cylinder heating device according to the first embodiment of the present invention is installed on the base plate 53 and a non-contact temperature sensor 82 that measures the temperature of the liquefied gas cylinder 2 in contact with the heating plate 52 It is also possible to further include.

Although the non-contact temperature sensor 82 is not shown in the drawing, it may be installed on the assembly support plate 51.

As shown in FIG. 4, the non-contact temperature sensor 82 may be installed at the center of the induction coil of the heating plate 52.

When the non-contact temperature sensor 82 is installed on the heating plate 52 as described above, it is possible to detect the temperature of a portion heated by the induction coil of the heating plate 52 in close proximity.

In the case of a conventional jacketed heater, since only the temperature of the heater is sensed, it is difficult to cope with the temperature change of the liquefied gas cylinder itself.

For example, due to the structure of the cabinet 10 storing the liquefied gas cylinder 2, the liquefied gas cylinder 2 is mounted vertically, and the liquefied gas cylinder 2 is in close contact with the heating plate 52. Even if the string 58 was tightened, the cabinet 10 was installed in an uneven area, the liquefied gas cylinder 2 was installed at an inclined position, or a vibration occurred near the cabinet 10, or the liquefied gas A gap may occur between the liquefied gas cylinder 2 and the heating plate 52 due to various reasons such as a difference in the curvature of the outer circumferential surface of the cylinder 2 and the curvature of the heating plate 52. Therefore, although there is a possibility that a difference may occur between the temperature of the heating plate 52 and the temperature of the liquefied gas cylinder 2, when the induction coil is controlled only by the temperature of the heating plate 52, the actual temperature of the liquefied gas cylinder 2 is precisely controlled. Difficult to control

In addition, when the valve of the liquefied gas cylinder 2 is opened and the liquefied gas is supplied, the temperature at the top of the liquefied gas cylinder 2 decreases instantly due to the vaporization phenomenon, thereby affecting the bottom of the liquefied gas cylinder 2. In some cases, the temperature in the vicinity of the heating plate 52 which is heated insanely decreases. However, since the contact-type temperature sensor only senses the temperature of the heating plate 52 or the inductor wire coil, the induction coil cannot be operated in real time despite the difference in temperature between the heating plate 52 and the liquefied gas cylinder 2.

Therefore, in the first embodiment of the present invention, the temperature of the liquefied gas cylinder 2, not the heating plate 52, is continuously monitored using the non-contact temperature sensor 82, and the controller 80 is the non-contact temperature sensor 82 In response to the temperature of the liquefied gas cylinder 2 detected from ), the operation of the induction coil installed on the heating plate 52 is dynamically controlled.

For example, the controller 80 controls the induction coil of the heating plate 52 to operate when the measured value of the non-contact temperature sensor 82 is below a set temperature (eg, 40° C.), and the non-contact temperature When the measured value of the sensor 82 exceeds a set temperature, it is also possible to control so that the operation of the induction coil of the heating plate 52 is stopped.

In addition, when the temperature sensed by the non-contact temperature sensor 82 is lower than a set temperature, the controller 80 applies a voltage to the induction coil of the heating plate 52 or controls the applied voltage to increase, and the non-contact type When the temperature sensed by the temperature sensor 82 is higher than the set temperature, the voltage applied to the induction coil of the heating plate 52 may be lowered or controlled to be cut off.

A non-contact temperature sensor 82 is installed to sense the temperature of the liquefied gas cylinder 2 as described above, and the controller 80 controls the operation of the induction coil of the heating plate 52 according to the temperature of the liquefied gas cylinder 2 If configured so as to be, it is possible to always keep the temperature of the liquefied gas cylinder 2 constant, and it is possible to keep the amount of the liquefied gas vaporized constant.

As the non-contact temperature sensor 82, an infrared temperature sensor, a laser temperature sensor, or the like may be used.

When the non-contact temperature sensor 82 is used in the above, it is possible to effectively detect the temperature of the liquefied gas cylinder 2 even in an environment where it is difficult to completely contact the liquefied gas cylinder 2 and the heating plate 52.

In general, when the capacity of the liquefied gas cylinder 2 is large, the temperature change of the heated part is very large. In particular, when the supply of liquefied gas is started and discharged, it takes a lot of heat, so the surface temperature of the liquefied gas cylinder 2 It is necessary to detect accurately and quickly.

By installing using the non-contact temperature sensor 82 as described above, it is always possible to accurately and quickly detect and respond to the temperature of the liquefied gas cylinder 2.

It is also possible to install close contact straps 58 for winding and fixing the liquefied gas cylinder 2 at both outer corners of the base plate 53 in the circumferential direction.

The heating plate 52 and the assembly support plate 51 may be formed of an elastic material that can be deformed so as to maintain a state in close contact with the outer circumferential surface of the liquefied gas cylinder 2.

It is also possible to form the fixing structure of both ends of the adhesive strap 58 by a Velcro method or a ratchet method so that the length can be freely adjusted and fixed.

The heating plate 52, the assembly support plate 51, and the base plate 53 are configured to be integrally fixed to each other in an assembled state, and constitute the induction module 50 as a set.

1 shows an example of a cabinet 10 configured to store the liquefied gas cylinder 2.

The induction module 50 is assembled and installed on the rear plate 16 of the cabinet 10.

A liquefied gas cylinder 2 is installed inside the cabinet 10.

The cabinet 10 includes a box-shaped cabinet body 11 and a front door 15 for opening and closing the front portion of the cabinet body 11.

It is also possible to install wheels 19 on the bottom of the cabinet body 11 to facilitate movement.

A mounting plate 17 that contacts and supports the loaded liquefied gas cylinder 2 is installed on the inner rear plate 16 of the cabinet 10.

It is preferable that the mounting plate 17 is installed at intervals from the induction module 50 to support the liquefied gas cylinder 2 at intervals in the longitudinal direction.

It is also possible to install a close contact string 58 that winds and fixes the liquefied gas cylinder 2 on the mounting plate 17.

When the surface of the mounting plate 17 in contact with the liquefied gas cylinder 2 is formed in an arc-shaped curved surface, it is possible to support the liquefied gas cylinder 2 more stably.

A non-contact temperature sensor 82 installed on the base plate 53 or the heating plate 52 so that the mounting plate 17 can also measure the temperature of a portion of the liquefied gas cylinder 2 that does not contact the heating plate 52 ) It is also possible to install a non-contact auxiliary temperature sensor 83 separately.

The non-contact auxiliary temperature sensor 83 is installed at a distance from the non-contact temperature sensor 82 installed on the base plate 53 or the heating plate 52 to accurately detect the temperature of the liquefied gas cylinder 2 as a whole. It is preferable because it is possible.

In the controller 80, the measured value of the non-contact auxiliary temperature sensor 83 is compared with the measured value of the non-contact temperature sensor 82 installed on the base plate 53 to dynamically operate the induction coil of the heating plate 52. It is also possible to configure to be controlled by.

When the controller 80 is configured to operate as described above, the operation of the induction coil of the heating plate 52 is not temporarily stopped even when the liquefied gas cylinder 2 in the area in contact with the heating plate 52 is locally overheated. Therefore, it is possible to keep the vaporization rate of the liquefied gas constant, and it is possible to constantly control the supply amount of the gas.

And, it is also possible to install the induction module 50 instead of the mounting plate 17, if necessary.

For example, as shown in FIG. 5, it is also possible to arrange and install two induction modules 50 at intervals at positions corresponding to the top and bottom of one liquefied gas cylinder 2.

The two induction modules 50 are installed so that the induction coils installed on the heating plate 52 are connected in parallel.

If two induction modules 50 are installed in one liquefied gas cylinder 2 as described above, even when a problem occurs in the induction coil of one induction module 50, the induction coil of the other induction module 50 is Since heating is performed on the liquefied gas cylinder 2 by using, it is possible to stably heat the liquefied gas cylinder 2.

If the induction module 50 is installed instead of the mounting plate 17 as described above, the liquefied gas cylinder 2 is heated in a wider range, so even when the length of the liquefied gas cylinder 2 is long, it is more efficient. As a result, it is possible to heat the liquefied gas cylinder 2.

And, if two induction modules 50 are installed corresponding to one liquefied gas cylinder 2, after replacing the liquefied gas cylinder 2, there is not enough waiting time before supplying the liquefied gas and immediately liquefied gas When supplying the liquefied gas with a large amount of usage, it is possible to shorten the time for heating the liquefied gas cylinder 2 to the required temperature even if the temperature drops rapidly.

In the above, the interior of the cabinet 10 may be configured to allow one liquefied gas cylinder 2 to be installed, and it is also possible to configure two or more liquefied gas cylinders 2 to be installed.

At the upper end of the cabinet 10, a connector, an opening/closing valve, a pressure gauge, and the like are installed to be connected to the outlet of the liquefied gas cylinder 2.

The cabinet 10 may be implemented by applying a general structure of a cabinet for storing the liquefied gas cylinder 2 configured in various conventional structures.

When using the liquefied gas cylinder heating device according to the first embodiment of the present invention configured as described above, in the facility for supplying liquefied gas by storing the conventional liquefied gas cylinder 2, it is installed in the conventional cabinet 10 By replacing and installing the induction module 50 in the place of the plate 17 and installing the controller 80, it is possible to easily apply and implement.

It is also possible to install a loading table 14 on which the liquefied gas cylinder 2 is loaded on the upper surface of the bottom plate 12 of the cabinet 10.

It is also possible to install a load cell sensor 18 that detects the weight of the loaded liquefied gas cylinder 2 on the loading table 14.

As shown in FIG. 3, the measured value of the load cell sensor 18 is input to the controller 80.

The controller 80 compares the weight of the liquefied gas cylinder 2 loaded on the loading table 14 detected through the load cell sensor 18 with a set weight value, and the replacement timing of the liquefied gas cylinder 2 and It is also possible to configure to display using a display device 88 such as an LED or LCD by determining whether to be loaded.

As shown in FIG. 1, the display device 88 may be installed on the top of the cabinet 10 so that it can be easily checked from the outside.

In addition, by installing one or more object detection sensors 56 on the surface (inner surface) of the base plate 51 in contact with the liquefied gas cylinder 2, the liquefied gas cylinder 2 is accurately It is also possible to configure it to check whether it is installed in a contact state.

The controller 80 may be configured to receive a detection signal from the object detection sensor 56 to check whether it is in close contact with the liquefied gas cylinder 2 and to determine whether to apply power to the heating plate 52.

It is also possible to install only one object detection sensor 56 on one of the upper or lower sides of the base plate 51.

The object detection sensor 56 may be installed in pairs on the upper and lower portions of the base plate 51, respectively.

If the object detection sensor 56 is installed in pairs at the upper and lower portions as described above, it is preferable because it is possible to easily check whether the outer circumferential surface of the liquefied gas cylinder 2 is installed in close contact with the heating plate 52 as a whole. .

For example, when the liquefied gas cylinder 2 is in contact with the heating plate 52 in a slightly inclined state, the detection signal is not detected by any one object detection sensor 56 installed at the upper or lower part. It is possible to accurately detect whether the liquefied gas cylinder 2 and the heating plate 52 are in contact.

The controller 80 is configured to send a warning signal through the display device 88 when the loading position of the liquefied gas cylinder 2 from the object detection sensor 56 is not in close contact with the heating plate 52. It is possible.

A pressure sensor 84 may be installed in a pipe connected to the outlet of the liquefied gas cylinder 2 installed in the cabinet 10 to sense the pressure of the supplied gas.

As shown in FIG. 3, the controller 80 determines a temperature measurement value and a pressure value input from the non-contact temperature sensor 82 and the pressure sensor 84 installed on the base plate 51, and liquefies the value above the set value. It is also possible to configure to determine whether or not power is applied to the induction coil of the heating plate 52 so that the gas cylinder 2 is overheated or cooled below a set value so that the liquefied gas is not supplied smoothly.

When the induction module 50 is configured as described above and installed on the rear plate 16 of the cabinet 10, the heater jacket is removed every time when a conventional heater jacket is used when the liquefied gas cylinder 2 is mounted or removed. Since there is no need to perform the cumbersome work of fastening and fastening, the replacement work of the liquefied gas cylinder 2 is made easily and quickly.

And, as shown in Figure 6, the liquefied gas cylinder heating device according to the second embodiment of the present invention includes a fastening guide member 46 for movably supporting the induction module 50 in the interior of the cabinet 10. Install.

The fastening guide member 46 is installed long in the horizontal direction on the inner surface of the rear plate 16 of the cabinet 10.

The fastening guide member 46 is configured and installed to move and support the induction module 50 to a position capable of stably supporting the liquefied gas cylinder 2.

For example, a movable groove 47 is formed on a surface of the fastening guide member 46 facing the liquefied gas cylinder 2 in the longitudinal direction, and the rear surface of the induction module 50 is formed in the movable groove 47. It is also possible to install the assembly protrusion formed in the sliding movement.

The fastening guide member 46 may also be installed at a position where the mounting plate 17 is installed, so that the mounting plate 17 is also movable.

And, the liquefied gas cylinder heating apparatus according to the third embodiment of the present invention, as shown in Figs. 7 and 8, including a heating plate 52, an assembly support plate 51, and a fastening guide member 46 Done.

The heating plate 52 and the assembly support plate 51 constitute one induction module 50.

An induction coil is installed on the heating plate 52.

A non-contact temperature sensor 82 and an object detection sensor 56 are installed on the assembly support plate 51.

The configuration of the non-contact temperature sensor 82 and the object detection sensor 56 installed on the assembly support plate 51 is a non-contact temperature sensor 82 and an object detection sensor installed on the base plate 53 of the first embodiment ( 56), the detailed description is omitted since it is possible to carry out the same configuration.

The non-contact temperature sensor 82 may be installed on the heating plate 52.

It is also possible to install a contact-type temperature sensor 81 on the heating plate 52.

In the induction module 50 of the third embodiment configured as described above, unlike the first and second embodiments, the base plate 53 is not additionally installed.

The basic configuration of the heating plate 52, the assembly support plate 51, and the fastening guide member 46 can be implemented in the same configuration as in the first and second embodiments described above, and a detailed description thereof will be omitted.

The third embodiment is not composed of a cabinet 10 storing the liquefied gas cylinder 2 in a state where the slopes are closed, as in the first and second embodiments, but the liquefied gas cylinder ( This is a configuration applied to the case of storing 2).

The fastening guide member 46 is installed to move toward the liquefied gas cylinder 2 by supporting the induction module 50.

In addition, the liquefied gas cylinder heating apparatus according to the third embodiment of the present invention further includes a bottom plate 12 on which the liquefied gas cylinder 2 is loaded.

It is also possible to install a loading table 14 on which the liquefied gas cylinder 2 is loaded on the upper surface of the bottom plate 12.

It is also possible to install a load cell sensor 18 that detects the weight of the loaded liquefied gas cylinder 2 on the loading table 14.

It is also possible to install a variable support column 40 on one side of the bottom plate 12, and install the fastening guide member 46 to the variable support column 40 so as to move upwardly.

The variable support pillar 40 may be installed on the bottom plate 12 so that it can be moved back and forth or rotated.

For example, if the lower end of the variable support column 40 is installed so that it can be moved back and forth on the bottom plate 12, when loading or unloading the liquefied gas cylinder 2, the variable support column 40 is loaded. The variable support column 40 is moved away from the table 14, and when the induction module 50 is in close contact with the liquefied gas cylinder 2, the variable support column 40 is approached to the loading table 14. It is possible to move it to the side.

Therefore, when loading or unloading the liquefied gas cylinder 2, it is possible to eliminate the fastening guide member 46 and the induction module 50 being caught or obstructed.

In addition, the lower member 42 of the variable support column 40 is installed in a state fixed to the bottom plate 12, and the column member 44 is rotatably assembled to the lower member 42. It is also possible to install.

In the inner side of the bottom plate 12 of the column member 44, a coupling groove 45 is formed vertically, and a coupling protrusion 48 of the fastening guide member 46 in the coupling groove 45 It is also possible to install it by combining it to be able to slide.

In the above, between the coupling protrusion 48 of the coupling guide member 46 and the coupling groove 45, a fixing member such as a bolt or a projection to restrain the upward movement of the coupling guide member 46 at a certain position (not shown in the drawing) It is also possible to install.

It is also possible to implement the upward movement of the fastening guide member 46 by using a motor or a hydraulic cylinder.

A moving groove 47 is formed long in the longitudinal direction on the inner surface of the bottom plate 12 of the fastening guide member 46, and the fastening protrusion 66 of the induction module 50 in the moving groove 47 It is also possible to install by combining) so that it can slide.

It is also possible to install a fixing member (not shown in the drawing) such as a bolt or a protrusion between the fastening protrusion 66 of the induction module 50 and the moving groove 47 to restrict the movement of the induction module 50 at a certain position. It is possible.

The fastening protrusion 66 is formed to protrude from the center of the outer circumferential surface of the induction module 50.

In the above, it is also possible to implement the movement of the induction module 50 using a motor or a hydraulic cylinder.

As described above, when the column member 44 is rotatably assembled to the lower member 42 and installed in a state in which the fastening guide member 46 is coupled to the column member 44, the bottom plate 12 is loaded. When loading or unloading the liquefied gas cylinder 2 on the table 14, the fastening guide 48 is positioned on the outside of the bottom plate 12 as the column member 44 is rotated outward (Fig. 7), it does not interfere with loading and unloading the liquefied gas cylinder (2).

In addition, as the column member 44 is rotated inward while the liquefied gas cylinder 2 is loaded and seated on the loading table 14 of the bottom plate 12, the fastening guide member 48 becomes liquefied gas. The induction module 50 is brought into close contact with the liquefied gas cylinder 2 (indicated by a solid line in Fig. 7).

The assembly support plate 51 of the induction module 50 is formed in a curved shape, and a heating plate 52 is installed inside the assembly support plate 51, and induction coils are arranged at regular intervals on the heating plate 52 to be installed. do.

It is preferable that the induction coil is arranged and installed so as to be evenly distributed over the entire area of the heating plate 52 if possible, since it is possible to efficiently heat the liquefied gas cylinder 2.

It is also possible to install the fixed support pillar 20 on the bottom plate 12 at a corner adjacent to the edge where the variable support pillar 40 is installed.

The fixed support column 20 is mounted on a column member 22 fixedly installed on one side of the bottom plate 12, and installed on the column member 22 and loaded on the loading table 14 of the bottom plate 12. It is also possible to include a curved seating member 24 for supporting a portion of the outer circumferential surface of the liquefied gas cylinder 2.

It is also possible to install the seating member 24 by arranging two or more vertically at regular intervals.

The seating member 24 may be installed to be movable up and down.

When the fixing support column 20 is installed as described above, the induction module 50 installed on the fastening guide member 46 in a state in which the liquefied gas cylinder 2 is loaded on the loading table 14 of the bottom plate 12. ) To the liquefied gas cylinder 2, it is possible to stably support the liquefied gas cylinder 2 without shaking.

In addition, as shown in FIG. 9, the induction module 50 may be formed such that the length thereof is variable by moving in a state of being divided into both sides of the center along the circumferential direction of the liquefied gas cylinder.

The induction module 50 is installed to move in both directions along the circumferential direction of the liquefied gas cylinder 2 to the fixing member 60 movably coupled to the fastening guide member 46 and the fixing member 60 And a pair of moving members 54 in which the heating plate 52 is installed.

It is also possible to install close contact strings 58 for winding and fixing the circumference of the cylindrical liquefied gas supply facility at both outer edges in the circumferential direction of the moving member 54.

It is preferable that the fixing member 60 and the moving member 54 be formed of a deformable elastic material to maintain a state in close contact with the outer circumferential surface of the liquefied gas cylinder.

It is also possible to install an elastic portion 55 having a variable length at the corner portions of the pair of moving members 54 located adjacent to each other.

The elastic part 55 may be composed of an elastic band formed in a corrugated state, and may be configured using an elastic band or a coil spring.

The end portion of the elastic part 55 is installed in a state that is fixed to the partition member 64 installed across the center of the fixing member 60.

The partition member 64 of the fixing member 60 is provided with a fastening protrusion 66 that is coupled to the moving groove 47 formed in the fastening guide member 46.

It is also possible to form a guide groove 62 through which both edges of the pair of moving members 54 are inserted into the fixing member 60 to guide the movement.

When the induction module 50 is configured as described above, the moving member 54 is in close contact with the outer circumferential surface of the liquefied gas cylinder 2 by using a contact strap 58 corresponding to the diameter of the liquefied gas cylinder 2 It can be fixed to, and a state in which a certain tension acts on the moving member 54 by the elastic force of the elastic portion 55 is maintained.

And, as shown in Fig. 10, the liquefied gas cylinder heating apparatus according to the fourth embodiment of the present invention includes two or more fixing support columns 20 so that two or more liquefied gas cylinders are loaded on the bottom plate 12. And, the induction module 50 is installed in a plurality of the fastening guide member 46 corresponding to each liquefied gas cylinder.

If configured as described above, it is possible to heat two or more liquefied gas cylinders 2 at the same time.

In the above, a preferred embodiment of the liquefied gas cylinder heating device according to the present invention has been described, but the present invention is not limited thereto, and various modifications can be made within the scope of the claims, the description of the invention, and the accompanying drawings. , This also falls within the scope of the present invention.

2-pressure vessel, 10-cabinet, 11-cabinet body, 12-bottom plate
14-loading table, 15-front door, 16-rear plate, 17-mounting member
18-load cell sensor, 19-wheel, 20-fixed support column, 22-column member
24-Seating member, 40-Variable support column, 42-Lower member, 44-Column member
45-coupling groove, 46-fastening guide member, 47-moving groove, 48-coupling protrusion
50-induction module, 51-assembly support plate, 52-induction coil, 53-base plate
54-moving member, 55-elastic part, 56-object detection sensor, 58-adhesive strap
60-fixing member, 62-guide groove, 64-partition member, 66-fastening protrusion
80-controller, 81-contact temperature sensor, 82-non-contact temperature sensor
83-auxiliary non-contact temperature sensor, 84-pressure sensor, 88-display

Claims (8)

A heating plate in which an induction coil formed in a curved shape corresponding to an arc surface is installed therein,
An assembly support plate on which the heating plate is installed and supported,
A base plate on which the assembly support plate is mounted and supported,
A contact-type temperature sensor installed on the heating plate and measuring the temperature of the heating plate,
Liquefied gas cylinder heating apparatus comprising a controller configured to control the operation of the induction coil installed on the heating plate in response to the temperature of the heating plate detected by the contact-type temperature sensor. The method according to claim 1,
It is installed on the heating plate and further comprises a non-contact type temperature sensor for measuring the temperature of the liquefied gas cylinder,
The controller includes a controller configured to dynamically control an operation of an induction coil installed on the heating plate in response to a temperature of the liquefied gas cylinder detected by the non-contact temperature sensor. The method according to claim 2,
Further comprising a non-contact auxiliary temperature sensor installed at a distance from the non-contact temperature sensor to measure the temperature of the liquefied gas cylinder portion not in contact with the heating plate,
The controller is a liquefied gas cylinder heating device configured to dynamically control an operation of an induction coil installed on the heating plate while comparing the measured value of the non-contact auxiliary temperature sensor with a set reference value. The method according to claim 1,
One or more object detection sensors are installed on the surface of the base plate or the assembly support plate in contact with the liquefied gas cylinder,
The controller is configured to operate the induction coil of the heating plate when the liquefied gas cylinder is installed in close contact with the heating plate in response to a detection signal from the object detection sensor. The method according to claim 1,
Liquefied gas cylinder heating device in which a plurality of induction coils are connected in parallel to the heating plate. The method according to claim 1,
The heating plate, the assembly support plate, and the base plate constitute one induction module,
The induction module is a liquefied gas cylinder heating device installed on a rear plate of a cabinet in which the liquefied gas cylinder is stored so that the heating plate is in contact with the outer circumferential surface of the liquefied gas cylinder. The method of claim 6,
A loading table on which a liquefied gas cylinder is loaded is installed on the bottom plate of the cabinet,
Liquefied gas cylinder heating device to install a load cell sensor for detecting the weight of the liquefied gas cylinder to be loaded on the loading table. The method of claim 6,
The liquefied gas cylinder heating device in which two induction modules are installed on the rear panel of the cabinet at intervals up and down corresponding to one liquefied gas cylinder.

Images