KR102578692B1 - Purification apparatus of heavy hydrogen formed at heavy water electrolysis - Google Patents

Abstract

As the disclosed device for highly purifying deuterium generated by electrolysis of heavy water includes a deuterium supply tank, a filtering member, and a concentration cooling tower, there is an advantage in that the deuterium generated by electrolysis of heavy water can be highly purified.

Description

{Purification apparatus of heavy hydrogen formed at heavy water electrolysis}

The present invention relates to a device for highly purifying deuterium generated from heavy water electrolysis.

Deuterium can be obtained by electrolysis of heavy water, but in order to be used industrially, such deuterium must be highly purified to 99.99% purity.

The patent document presented below can be presented as a method for producing such deuterium gas.

However, according to the conventional method of producing deuterium gas, there was a problem in that it was difficult to achieve high purity of deuterium.

Publication Patent No. 10-2007-0112138, Publication Date: 2007.11.22., Title of Invention: Method for producing deuterium gas, and catalytic deuteration method using deuterium gas obtained by this method.

The purpose of the present invention is to provide a device for highly purifying deuterium produced by electrolysis of heavy water, which can purify deuterium produced by electrolysis of heavy water.

A device for high purification of deuterium generated by electrolysis of heavy water according to one aspect of the present invention includes a deuterium supply tank that supplies deuterium generated by electrolysis of heavy water; a filtering member that removes foreign substances in the deuterium supplied from the deuterium supply tank; a concentration cooling tower that cools and concentrates the deuterium that has passed through the filtering member; And a shock detection irreversibility confirmation unit capable of detecting an external shock applied from the outside to the concentrated cooling tower and irreversibly maintaining the state in which the external shock has been detected.
The impact sensing irreversible confirmation unit includes a base member placed on an installation surface on which the concentrated cooling tower is installed, a support insertion member fixed to a lower part of the concentrated cooling tower and protruding toward the base member, and a support member that is detachable from the base member. An impact moving member that is raised and can be inserted into the supporting insertion member by the external shock transmitted through the base member, and is interposed between the impact moving member and the supporting insertion member before the external shock is applied. The support insertion member is connected to be supported by the impact movable member and the base member, and when the external impact is applied, the shock movable member is crushed by the external impact and is inserted into the support insertion member. A member is fixed to a portion of the lower part of the concentrated cooling tower adjacent to the supporting member, and is in contact with the base member while receiving air and maintaining an expanded state, and then the impact-crushing member is caused by the external impact. An air tank member that discharges the air while being crushed and pressed by the base member when the impact moving member is inserted into the support insertion member, is fixed to the support insertion member, and is in a non-contact state with the base member while facing the base member. While maintaining, the shock-crushing member is crushed by the external impact, and as the impact moving member is inserted into the support insertion member, it protrudes by the air discharged from the air tank member and comes into contact with the base member to support the support. It is characterized by including an impact protruding support member that supports the insertion member.

According to an apparatus for highly purifying deuterium generated in heavy water electrolysis according to an aspect of the present invention, the apparatus for highly purifying deuterium generated in heavy water electrolysis includes a deuterium supply tank, a filtering member, and a concentration cooling tower, This has the effect of making it possible to highly purify the heavy hydrogen produced by electrolyzing heavy water.

Figure 1 is a diagram showing the configuration of a device for highly purifying deuterium generated from heavy water electrolysis according to an embodiment of the present invention.
Figure 2 is an enlarged view showing a shock-sensing irreversible confirmation unit constituting a device for high purification of deuterium generated from heavy water electrolysis according to an embodiment of the present invention.

Hereinafter, a device for highly purifying deuterium generated from heavy water electrolysis according to an embodiment of the present invention will be described with reference to the drawings.

Figure 1 is a diagram showing the configuration of a device for highly purifying deuterium generated in heavy water electrolysis according to an embodiment of the present invention, and Figure 2 is a diagram showing the high purity of deuterium generated in heavy water electrolysis according to an embodiment of the present invention. This is an enlarged view showing the shock detection irreversible confirmation unit that makes up the device.

Referring to FIGS. 1 and 2 together, the device 100 for high purification of deuterium generated from heavy water electrolysis according to this embodiment includes a deuterium supply tank 110, a filtering member 120, and a concentration cooling tower 130. Includes.

The deuterium supply tank 110 stores and supplies deuterium generated by electrolyzing heavy water.

Drawing number 101 is a supply pipe extending from the deuterium supply tank 110 through which the deuterium flows.

The filtering member 120 is installed on the supply pipe 101 to remove foreign substances such as oxygen in the deuterium supplied from the deuterium supply tank 110.

The concentration cooling tower 130 is installed on the supply pipe 101 to cool and concentrate the deuterium passing through the filtering member 120.

To enable cooling and concentration of the deuterium in the concentration cooling tower 130, a refrigerator 135 having a refrigeration cycle is connected to the concentration cooling tower 130, so that the concentration cooling tower 130 flows from the refrigerator 135 to the concentration cooling tower 130. Cold air is supplied.

Drawing number 140 is a high-purity deuterium storage tank connected to the end of the supply pipe 101 and storing the deuterium concentrated in the enrichment cooling tower 130.

Meanwhile, the device 100 for high purification of deuterium generated from heavy water electrolysis according to this embodiment further includes an impact detection irreversibility confirmation unit 200.

The shock detection irreversibility confirmation unit 200 is capable of detecting an external shock applied from the outside to the concentrated cooling tower 130 and irreversibly maintaining the state in which the external shock is detected.

In detail, the impact sensing irreversible confirmation unit 200 includes a base member 210, a support insert member 240, an impact moving member 220, an impact crushing member 230, and an air tank member 250. and an impact protruding support member 270.

The base member 210 is placed on the installation surface where the concentrated cooling tower 130 is installed.

The base member 210 is formed in the form of a plate with a predetermined area and includes a base plate 211 placed on the installation surface where the concentrated cooling tower 130 is installed, and upward from both sides of the base plate 211. A pair of base vertical bodies 212 extending to a predetermined height, and a pair of bases each protruding upward at a predetermined height at a certain portion between the center of the base plate 211 and each of the base vertical bodies 212. It includes a protrusion 213 and an impact movement insertion hole 214 that is recessed to a predetermined depth in the upper surface of the central portion of the base plate 211 and into which the lower part of the impact movement member 220 can be removably inserted. do.

The support insertion member 240 is fixed to the lower part of the refrigerant accommodating case 131, which is the lower part of the concentrated cooling tower 130, and protrudes toward the base member 210.

The support insertion member 240 includes a support insertion protrusion 241 that is fixed to the lower part of the refrigerant accommodating case 131 and protrudes downward from the refrigerant accommodating case 131 and has a hemispherical cross section, and It protrudes from the lower part of the protruding body 241 toward the impact moving member 220 and includes a support clamping body 242 protruding in pairs to be spaced apart from each other.

When the upper part of the impact moving member 220 is inserted into the supporting clamping body 242, the supporting clamping body 242 is elastically deformed and spread, and the upper part of the impact moving member 220 is inserted. When completed, the support clamping body 242 tightens the upper part of the impact moving member 220 by restoring force, thereby preventing the impact moving member 220 from falling from the supporting member 240.

The shock moving member 220 is detachably mounted on the base member 210 and can be inserted into the support insertion member 240 by the external shock transmitted through the base member 210. will be.

The shock movable member 220 is formed in the form of a plate with a predetermined area and includes a shock movable lower body 221 detachably inserted into the shock movable insertion hole 214, and a predetermined height from the center of the shock movable lower body 221. It includes an impact moving upper body 222 that is erected.

The upper part of the impact moving upper body 222 is formed in a tapered shape so that it can be smoothly inserted between the supporting insert clamping bodies 242.

The impact-crushing member 230 is interposed between the impact-moving member 220 and the supporting insertion member 240 before the external impact is applied, so that the supporting insertion member 240 is connected to the impact-moving member 220. And it is connected to be supported by the base member 210, and when the external impact is applied, the impact moving member 220 is inserted into the support insertion member 240 while being broken by the external impact.

The impact-crushable member 230 is formed in the shape of a plate with a predetermined area, the impact-moving upper body 222 is in contact with the bottom center of the impact-crushable member 230, and the upper surface of the impact-crushable member 230 The lower ends of each of the supporting clamping bodies 242 are in contact with two points that are symmetrical to each other and are eccentrically spaced at a predetermined distance from the center. Then, the bottom center of the impact-crushable member 230 is pressed by the impact-movable upper body 222, and two points are symmetrical to each other and are eccentric to be spaced a predetermined distance from the top-center part of the impact-crushable member 230. maintains a state of being pressed by each of the supporting clamping bodies 242, and when the external shock is applied, the external shock is transmitted through the shock moving upper body 222 to the center portion of the bottom of the shock-crushing member 230. When applied to the external shock and the eccentric pressing force of each support clamping body 242, the impact crushable member 230 can be broken and crushed.

When the impact-crushable member 230 is crushed, fragments of the impact-crushable member 230 fall to the base plate 211, and accordingly, the support piece supported by the impact-crushable member 230 As the member 240 is lowered, the impact moving upper body 222 can be inserted between each of the supporting clamping bodies 242.

The air tank member 250 is fixed to a portion of the lower part of the refrigerant accommodating case 131 constituting the concentrated cooling tower 130 adjacent to the support insertion member 240, and is in an expanded state by receiving air. While maintaining the contact with each base vertical body 212 of the base member 210, the impact-crushing member 230 is crushed by the external impact, and the impact moving member 220 is the support insertion member. When inserted into 240, the air is discharged while being pressed by each base vertical body 212.

The air tank member 250 is disposed in a portion of the lower portion of the refrigerant storage case 131 adjacent to the support insertion member 240, has an oval cross-section that is longer at a predetermined length from side to side compared to the top and bottom, and has a hollow interior. It is formed in a shape to accommodate the air, and is made of an elastic material such as rubber.

The air tank members 250 are installed one by one on both side portions of the lower part of the refrigerant accommodating case 131 adjacent to the support insertion member 240 and face each of the base vertical bodies 212.

A load cell 260 is mounted on the air tank member 250, and the air is discharged while the air tank member 250 is pressed by the base vertical body 212, that is, the external shock is applied. This can be sensed by the load cell 260 and transmitted to the outside.

The impact protruding support member 270 is fixed to the support insertion member 240 and faces the base protrusion 213 of the base member 210 while facing the base protrusion 213 of the base member 210. ) is maintained in a non-contact state, and the shock-crushing member 230 is crushed by the external impact, and the impact moving member 220 is inserted into the support insertion member 240, thereby causing the air tank member 250 It supports the support insertion member 240 by contacting the base protrusion 213 of the base member 210 while protruding by the air discharged from the base member 210.

The impact protruding support member 270 is disposed to face the base protruding body 213 from the supporting protruding member 241 of the supporting inserting member 240 and connects the air tank member 250 and the air flow pipe 255. ) and an impact protrusion cylinder 271 connected by a shock protrusion piston 272 that can be moved up and down along the inside of the impact protrusion cylinder 271.

Normally, when the external shock is not applied, the air tank member 250 maintains an expanded state, so that the shock protruding cylinder 271 connected to the air tank member 250 and the air flow pipe 255 Negative pressure is applied inside to maintain the impact protrusion piston 272 inserted into the interior of the impact protrusion cylinder 271, and accordingly, the impact protrusion piston 272 is attached to the base protrusion 213. ) and maintain non-contact status.

On the other hand, when the shock moving member 220 is inserted into the supporting insertion member 240 while the shock-crushing member 230 is crushed by the external impact, the air discharged from the air tank member 250 is The air flows into the inside of the impact protrusion cylinder 271 by the air flow pipe 255, so that the impact protrusion piston 272 protrudes from the impact protrusion cylinder 271, and accordingly, the impact protrusion piston 272 protrudes from the impact protrusion cylinder 271. It comes into contact with the base protrusion 213 to support the support insertion member 240.

A pair of impact protruding support members 270 is installed on the support insertion member 240 to face each of the base protrusions 213.

In normal times when the external shock is not applied, the impact moving member 220 is placed on the base member 210, and the impact crushing member 230 is placed on the impact moving member 220, The support insertion member 240 is placed on the impact crushing member 230, and the base member 210, the impact moving member 220, the impact crushing member 230, and the support insertion member ( 240) and the concentrated cooling tower 130 are arranged in a stacked form, the air tank member 250 is maintained in an expanded state, and the base member 210 and the air tank member 250 are in a pressurized state. Otherwise, the simple contact state is maintained, and the impact protruding support member 270 maintains a non-contact state with the base member 210.

Then, when the external shock is transmitted through the base member 210, the shock-crushed member 230 is crushed by the external shock, causing the support inserted member 240 and the concentrated cooling tower 130 to be lowered. Accordingly, the impact moving member 220 is inserted into the support insertion member 240, and the air tank member 250 is pressed by the base member 210 to release the air in the air tank member 250. is transmitted to the impact protruding support member 270, and the impact protrusion support member 270 is in contact with the base member 210, and the support is inserted by the base member 210 and the impact protrusion support member 270. The member 240 and the concentrated cooling tower 130 can be supported.

When the base member 210 is removed by an operator or the like while the concentrated cooling tower 130 is lifted and supported by a separate support means (not shown) such as a crane, the impact moving member 220 is moved to the base member ( The state of being separated from 210 and inserted into the support insertion member 240 can be confirmed with the naked eye, and accordingly, it can be easily and immediately confirmed with the naked eye that the external shock has been applied to the concentrated cooling tower 130. , Unless there is additional artificial work by an operator, etc., the shock moving member 220 maintains the state inserted into the support insertion member 240, so that the state in which the external shock is applied is irreversibly maintained and confirmed. do.

Hereinafter, the operation of the device 100 for high purification of deuterium generated from heavy water electrolysis according to this embodiment will be described with reference to the drawings.

The deuterium generated by electrolyzing heavy water is supplied from the deuterium supply tank 110 and flows along the supply pipe 101.

The deuterium flowing along the supply pipe 101 flows through the filtering member 120 and flows into the concentration cooling tower 130 with foreign substances removed, and is highly purified as it is cooled and concentrated in the concentration cooling tower 130. do.

The deuterium that has become highly purified by being cooled and concentrated as described above is stored in the high-purity deuterium storage tank 140.

As described above, the device 100 for high purification of heavy hydrogen generated from the heavy water electrolysis includes the heavy hydrogen supply tank 110, the filtering member 120, and the concentrated cooling tower 130, thereby producing heavy water. The deuterium generated by electrolysis can be highly purified.

Although the present invention has been shown and described in relation to specific embodiments in the above, those skilled in the art can modify the present invention in various ways without departing from the spirit and scope of the present invention as set forth in the claims below. You will see that it can be changed. However, we would like to make it clear that all such modifications and modified structures are included within the scope of the present invention.

According to the device for highly purifying deuterium generated by electrolysis of heavy water according to one aspect of the present invention, the deuterium generated by electrolysis of heavy water can be highly purified, and thus its industrial applicability is high.

100: High purification device for deuterium generated from heavy water electrolysis
110: Deuterium supply tank
120: Absence of filtering
130: Concentration cooling tower

Claims (3)

A deuterium supply tank that supplies deuterium generated by electrolyzing heavy water;
a filtering member that removes foreign substances in the deuterium supplied from the deuterium supply tank;
a concentration cooling tower that cools and concentrates the deuterium that has passed through the filtering member; and
It includes a shock detection irreversible confirmation unit that detects an external shock applied to the concentrated cooling tower from the outside and irreversibly maintains the state in which the external shock was detected,
The shock detection irreversible confirmation unit is
a base member placed on an installation surface on which the concentrated cooling tower is installed;
a support insertion member fixed to a lower part of the concentrated cooling tower and protruding toward the base member;
an impact moving member that is detachably mounted on the base member and can be inserted into the support insertion member by the external shock transmitted through the base member;
Before the external shock is applied, it is interposed between the shock moving member and the support inserted member to connect the supporting inserted member to be supported by the shock moving member and the base member, and when the external shock is applied, the external shock is an impact-crushing member that is crushed by the impact-crushing member so that the impact-moving member is inserted into the support insertion member;
It is fixed to a portion of the lower part of the concentrated cooling tower adjacent to the supporting member, and is in contact with the base member while receiving air and maintaining an expanded state. Then, the impact-crushing member is crushed by the external impact, an air tank member that discharges the air while being pressed by the base member when the impact moving member is inserted into the support insertion member;
It is fixed to the support insertion member and maintains a non-contact state with the base member while facing the base member, and as the impact crushing member is crushed by the external impact, the impact moving member is inserted into the support insertion member. A device for high purification of deuterium generated in heavy water electrolysis, comprising an impact protruding support member that is protruded by the air discharged from the air tank member and contacts the base member to support the support insertion member.
delete delete