KR102307988B1 - Flow rate regulator for intravenous fluid - Google Patents

Abstract

The present invention relates to a chemical liquid flow control device for quantitatively controlling the flow rate of a chemical, comprising a chemical liquid inlet passage and a chemical liquid outlet passage at the bottom of the body, and a pair of guides along the longitudinal direction on both side portions of the body. Chemical flow control body in which the hole is formed; Slide having a slide fastening part fastened to the guide hole in both lower sides of the base plate, a knob protruding from the upper part of the base plate, and a wedge part for indicating a flow rate extending from the knob and protruding in a wedge shape toward one side bar; a chemical liquid passage groove which is concavely formed to connect the chemical liquid inlet passage and the chemical liquid outlet passage as it is at the proximal end of the bottom surface of the slide bar; a chemical solution stopper disposed adjacent to the bottom end of the slide bar in the chemical solution passage groove and closing the chemical solution inlet passage and the chemical solution outlet passage; and a pressure control wall extending from the chemical stopper toward the tip of the bottom surface of the slide bar and extending the communication space between the chemical liquid inlet passage and the chemical liquid outlet passage toward the bottom tip of the slide bar.
According to the present invention, the user can control the flow rate by adjusting the flow rate with the finger of the hand holding the knob of the slide bar in the state that the user grips the chemical liquid flow control body, which has the advantage of convenient operation and free one hand, and the maximum volume of the flow rate By achieving an extremely short pitch from to stop, the operation period and operation time from injection of chemical to standby for operation can be greatly shortened. There is an effect that can be easily achieved.

Description

Chemical flow control device {FLOW RATE REGULATOR FOR INTRAVENOUS FLUID}

The present invention relates to a chemical liquid flow control device for quantitatively controlling the flow rate into which the chemical liquid is injected, and more particularly, it is convenient to operate by controlling the flow rate of the chemical liquid by operating a slide bar in a linear direction, and stops at the maximum volume of the flow rate. To achieve this with an extremely short pitch, it is possible to greatly shorten the operation from chemical injection to operation standby, and it relates to a chemical liquid flow control device of a new structure that facilitates quantitative control of the flow rate.

In general, a device for supplying by controlling the flow rate of a chemical has been applied in various fields. For example, a drug flow controller is used to quantitatively inject Ringer's solution into a patient.

International Publication Nos. WO 1986-000682 and WO 1998-009893 propose an intravenous drug flow control device having a relatively simple structure. However, since Ringer's solution is in direct contact with the flow path inside the flow control device, the material of the flow control device is limited, and it is difficult to use if the type of Ringer's solution is changed. In addition, it has a structure that is difficult to operate with one hand.

US Patent No. 4,332,369 adopts a method of pressing the tube through which Ringer's solution passes by using the principle of a screw (a principle of converting rotational motion into linear motion) in a state where Ringer's solution and the device are not in direct contact. However, it is difficult to commercialize due to its complex structure and frequent breakdowns.

1 to 3 illustrate an apparatus for regulating the flow rate of a chemical liquid currently widely used worldwide.

As shown in Figures 1 to 3, since the disk 14 has a structure that presses the tube 15 through which Ringer's solution passes, there is an advantage of having a simple structure consisting of only three parts.

However, in this flow control device, as shown in FIG. 3, the disk 14 operated by the thumb moves from the uppermost position 16 to the lowermost position 17 of the housing while rolling along the housing 13, While holding the housing with your index and middle fingers, it is quite unnatural to manipulate the disk that rolls along the housing with your thumb.

In addition, in the flow control device, when the length of the groove is lengthened so that the cross-sectional area of the groove 12 dug in the bottom of the housing is changed more gently in order to enable fine flow control, the length of the housing becomes longer, so that the length of the housing becomes longer. The operation of the control becomes more unnatural, resulting in a situation in which it becomes difficult to operate the flow control device with one hand. Furthermore, it is very difficult to accurately control the amount of the chemical in the method of controlling the amount of the chemical by rolling the disk 14.

On the other hand, Korean Patent No. 10-0578001 and Korean Patent No. 10-1058539 propose a device capable of relatively accurate flow rate control by improving the existing chemical liquid flow control device.

However, one of the major problems of the conventional chemical liquid flow control device is that the knob for controlling the flow rate is operated in a rotational manner. Since the knob must be rotated, one hand has no choice but to rotate the knob with the other hand while holding the body, so both hands are not free.

In addition, in the case of using the chemical flow control device, the flow rate is finely adjusted after stopping the flow rate after the chemical solution is sufficiently supplied from the Ringer dispenser to the patient by completely passing the chemical solution, but in the conventional rotary control structure From the stop of the flow to the maximum volume, rotate the knob to the maximum, then rotate it in the reverse direction as far as possible to stop the flow, and then rotate the knob in the forward direction again to adjust the flow. That is, the control method of the flow rate is cumbersome, mechanical damage may occur while rotating the knob twice in the maximum direction, and it is difficult to finely control the flow rate.

International Patent Publication No. WO 1986-000682 International Patent Publication No. WO 1998-009893 US Patent No. 4,332,369 Domestic Registered Patent Publication No. 10-0578001 Domestic Registered Patent Publication No. 10-1058539

The present invention adjusts the flow rate of the chemical solution in a linear motion method for convenient operation, and achieves an extremely short pitch from the maximum volume of the flow rate to the stop, thereby greatly shortening the operation from the chemical solution injection to the operation standby. The purpose is to provide a device.

The chemical liquid flow control device according to an embodiment of the present invention includes a chemical liquid inflow passage and a chemical liquid outflow passage at the bottom of the body, and a pair of guide holes are formed in both side portions of the body along the longitudinal direction. adjustable body; Slide having a slide fastening part fastened to the guide hole in both lower sides of the base plate, a knob protruding from the upper part of the base plate, and a wedge part for indicating a flow rate extending from the knob and protruding in a wedge shape toward one side bar; a chemical liquid passage groove formed concavely to connect the chemical liquid inlet passage and the chemical liquid outlet passage as it is at the base end of the slide bar; a chemical solution stopper disposed adjacent to the bottom end of the slide bar in the chemical solution passage groove and closing the chemical solution inlet passage and the chemical solution outlet passage; and a pressure control wall extending from the chemical stopper toward the tip of the bottom surface of the slide bar and extending the communication space between the chemical liquid inlet passage and the chemical liquid outlet passage toward the bottom tip of the slide bar.

In the chemical liquid flow control device according to another embodiment of the present invention, a flow rate display unit for displaying a flow rate corresponding to the flow rate indication wedge is formed on an upper surface of one side of the chemical liquid flow rate control body, and the flow rate display unit is at the base end. An open mark in which the chemical liquid completely passes toward the tip, a lock mark in which the distribution of the chemical liquid is closed, and a flow control scale mark indicating the flow rate control stage of the chemical liquid are sequentially displayed.

In the chemical liquid flow control device according to another embodiment of the present invention, a partition wall for partitioning the chemical solution passage groove, the chemical solution stop part, and the pressure control wall is formed on the bottom surface of the slide bar, and the perimeter of the partition wall is formed. An O-ring that blocks the outflow of the chemical is fastened to the sealing fastening groove formed accordingly.

In the chemical liquid flow control device according to another embodiment of the present invention, the pressure control wall is formed to decrease in height toward the bottom end of the slide bar.

In the chemical liquid flow control device according to another embodiment of the present invention, a flow rate control groove is formed to a predetermined depth along the longitudinal central axis of the pressure control wall.

In the chemical liquid flow control device according to another embodiment of the present invention, a chemical liquid circulation passage through which the chemical liquid is circulated is formed in communication with the flow rate control groove along the circumference of the pressure control wall.

In the chemical liquid flow control device according to another embodiment of the present invention, the chemical liquid circulation passage is formed in a U-shape along the circumference of the pressure control wall, the bottom surface of the slide bar is closed, and the front end is the flow control groove and formed to communicate.

In the chemical liquid flow control apparatus according to another embodiment of the present invention, the chemical liquid circulation passage is formed to have the same depth.

According to the chemical flow control device of the present invention, the user can control the flow rate by adjusting the flow rate with the finger of the hand holding the knob of the slide bar in a state in which the user holds the chemical solution flow control body, which has the advantage of convenient operation and free one hand. , by achieving an extremely short pitch from the maximum volume of the flow to the stop, the operation period and operation time from injection of chemical to standby for operation can be greatly shortened, and flow rate control can be started when the flow of chemical is completely stopped There is an effect that adjustment and fine adjustment can be easily achieved.

1 is a view illustrating a chemical liquid flow control device according to the prior art;
2 is a view illustrating a housing of a chemical liquid flow control device according to the prior art;
3 is a view showing the operating state of the chemical liquid flow control device according to the prior art;
4 is a perspective view showing the appearance of the chemical liquid flow control device according to the present invention;
5 is an exploded perspective view of the chemical liquid flow control device according to the present invention;
6 is a bottom perspective view illustrating the lower configuration of the slide operation unit in the present invention;
7 is a bottom view illustrating the lower configuration of the slide operation unit in the present invention;
8 is a cross-sectional view illustrating a drug distribution path in the present invention, and
9 is a plan view of the chemical liquid flow control device according to the present invention.

Hereinafter, specific embodiments according to the present invention will be described with reference to the accompanying drawings. However, this is not intended to limit the present invention to a specific embodiment, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Throughout the specification, the same reference numerals are given to parts having similar structures and operations. And, the drawings attached to the present invention are for convenience of description, and the shape and relative scale may be exaggerated or omitted.

In describing the embodiments in detail, overlapping descriptions or descriptions of obvious techniques in the art are omitted. In addition, when a certain part "includes" other components in the following description, it means that other components may be further included in addition to the described components unless otherwise stated.

In addition, terms such as "~ part", "~ group", "~ module", etc. described in the specification mean a unit that processes at least one function or operation, and when it is said that a part is connected to another part, it is It includes not only the case where it is directly connected, but also the case where it is connected through another configuration in the middle.

Terms including an ordinal number, such as first, second, etc., may be used to describe various elements, but the elements are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the second component may be referred to as the first component, and similarly, the first component may also be referred to as the second component.

Figure 4 is a perspective view showing the external appearance of the chemical liquid flow control device according to the present invention, Figure 5 is an exploded perspective view of the chemical liquid flow control device according to the present invention. The external structure of the chemical liquid flow control device of the present invention will be briefly described with reference to FIGS. 4 and 5 .

The chemical liquid flow control device of the present invention includes a slide bar 100 and a chemical liquid flow control body 400 , and has a configuration in which two seals are interposed between the slide bar 100 and the chemical liquid flow control body 400 . .

As will be described later in detail, one of the two seals is an O-ring (O-ring, 200) interposed between the slide bar coupling surface 420 of the chemical liquid flow control body 400 and the bottom surface 130 of the slide bar 100. As a result, the chemical solution is sealed so that the chemical solution does not flow out from the chemical solution distribution path in the device. The other seal is an inlet/outlet seal 300 coupled to an inlet/outlet sealing seating groove 412 formed in the center of the chemical liquid flow control body 400, the chemical liquid inlet passage through which the chemical is introduced into the device, and the chemical liquid out of the device. Seal the chemical liquid outlet passage. As illustrated in FIG. 5 , the inlet/outlet sealing 300 includes an inlet line through hole 310 through which the chemical liquid inlet passage passes and an outlet line through hole 320 through which the chemical liquid outlet passage passes.

On the other hand, in the description of the embodiment of the present invention, the chemical liquid inlet passage (or inlet line) and the chemical liquid outlet passage (or outflow line) will be described with reference to the reference numerals, but this is only a division to help the understanding of the present invention, Of course, when the chemical liquid flow control device is actually used, the chemical liquid inlet passage and the chemical liquid outlet passage may be used opposite to each other.

4 and 5 , the slide bar 100 has a shape in which the slide fastening parts 120 protrude downward to both lower sides of the base plate 110 , and the ends of each slide fastening part 120 have an inner side. A protruding locking protrusion 122 is formed. Correspondingly, a pair of guide holes 422 and 424 are formed in both side portions of the body portion 410 constituting the chemical liquid flow control body 400 along the longitudinal direction.

A pair of slide coupling parts 120 are inserted into the first guide hole 422 and the second guide hole 424, respectively, so that the slide bar 100 is assembled to the chemical liquid flow control body 400, and the slide coupling part The locking protrusion 122 of 120 is engaged with the bottom surface of the chemical liquid flow control body 400 . While the bottom surface 130 of the slide bar 100 and the slide bar coupling surface 420 of the chemical liquid flow control body 400 are kept in close contact with the O-ring 200, the slide bar moves the chemical liquid flow control body 400 It is slid in a linear direction with respect to (ie, in the longitudinal direction of the chemical liquid flow control body 400 ).

A knob 112 is formed to protrude from the center upper portion of the base plate 110 of the slide bar 100 , and a wedge portion 114 for indicating a flow rate extending from the knob 112 is formed to protrude toward one side.

On the first side upper surface 430 forming the upper surface of one side of the chemical liquid flow control body 400, the position corresponding to the wedge portion 114 for indicating the flow rate (precisely, the wedge portion 114 for indicating the flow rate indicates that the position) a flow rate display unit 432 is formed. As described in detail in FIG. 9 , the flow rate display unit 432 sequentially displays an open mark (Open), a lock mark (Close), and a flow rate adjustment scale from the proximal end to the distal end. The open mark indicates an open state in which the chemical liquid completely passes, and the close mark indicates a locked state in which the distribution of the chemical liquid is completely closed. The flow control scale displays the minimum flow adjacent to the lock mark and the maximum flow at the tip.

Here, the chemical liquid flow control device of the present invention is different from the conventional "Open-Minimum flow...Maximum flow-Close" flow control configuration and display, "Open-Close-Minimum flow.... .. has a control configuration and indication of “maximum flow”. This flow control configuration and indication provides the technical advantage that it can be achieved with an extremely short pitch from the maximum volume of the flow to a stop, from the first injection of the chemical to the pause of the flow of the chemical to wait for the operation to control the flow. It is possible to minimize the operation section and time of operation, and to start fine flow control when the flow of the chemical is completely stopped.

On the other hand, the side surface of the first side upper surface 430 of the chemical liquid flow control body 400, and the side of the second side upper surface 440 forming the other side upper surface, respectively, the anti-slip unevenness 442 is formed, , it is possible to prevent the body from slipping away from the hand when the user operates the knob 112 while holding the body body.

Figure 6 is a bottom perspective view illustrating the lower configuration of the slide operation part in the present invention, Figure 7 is a bottom view illustrating the lower configuration of the slide operation part in the present invention, Figure 8 is a cross-sectional view illustrating the chemical liquid distribution path in the present invention , Figure 9 is a plan view of the chemical liquid flow control device according to the present invention. With reference to FIGS. 6 to 9, the configuration of the chemical liquid flow rate control in the present invention and its effect will be described in detail as follows.

6 and 7 , the configuration of the bottom part 130 of the slide bar 100 is illustrated in detail. As shown, the chemical liquid passing groove 142, the chemical liquid stopper 144, and the pressure control wall 146 are sequentially formed from the bottom surface of the slide bar 100 toward the front end.

The chemical liquid passage groove 142 is a groove formed concavely to connect the chemical liquid inlet passage and the chemical liquid outlet passage as they are at the base end of the bottom surface of the slide bar 100 . The chemical liquid passing groove 142 is formed to a sufficient depth so that the chemical liquid passes completely without limitation.

The chemical liquid stopper 144 is disposed adjacent to the bottom end of the slide bar 100 in the chemical liquid passage groove 142 and closes the chemical liquid inlet passage and the chemical liquid outlet passage.

The pressure regulating wall 146 is a wall extending from the chemical stopper 144 toward the tip of the bottom of the slide bar 100 and extends the communication space between the chemical inflow passage and the chemical outflow passage toward the bottom tip of the slide bar 100 . It is an expanding composition.

The inlet pipe 468 through which the chemical is injected into the device according to the operation of the slide bar 100 and the outlet pipe 478 through which the chemical is discharged to the outside of the device are formed by the chemical solution passing groove 142, the chemical solution stopper 144, and the pressure tank. Before describing the process of moving the position along the cliff 146, a description will be given of how the chemical liquid inlet passage and the chemical liquid outlet passage are formed in the device with reference to FIG. 8 .

Referring to FIG. 8 , chemical liquid inlet passages 462 , 464 , 466 , 468 and chemical liquid outlet passages 472 , 474 , 476 and 478 are provided at the bottom of the body portion 410 of the chemical liquid flow control body 400 . . The drug inlet passage includes an inlet line fastening part 462 to which a drug inlet pipe connected to the Ringer's solution dispenser is fastened, and a first inlet line communicating part 464 and a second inlet line communicating with the inlet line fastening part 462 in a straight direction. It includes a communication part 466 and an inlet pipe 468 that is bent upward in the second inlet line communication part 466 and passes through the inlet line through hole 310 of the inlet/outlet sealing seal 300 . The drug outlet passage includes an outlet line coupling part 472 to which a drug solution outlet pipe connected to an injection needle inserted into a patient's vein is fastened, and a first outlet line communicating part 474 communicating in a straight line with the outlet line fastening part 472. and a second outlet line communicating part 476 and an outlet pipe 478 bent upward in the second outlet line communicating part 476 and passing through the outlet line through hole 320 of the inlet/outlet sealing seal 300 . .

Referring to FIG. 9 , when the slide bar 100 is located at the proximal end with respect to the chemical liquid flow control body 400 , that is, the wedge portion 114 for indicating the flow rate as in FIG. 9 opens the flow rate display unit 432 . When indicated, the ends of the inlet pipe 468 and the outlet pipe 478 in the device are positioned in the chemical liquid passage groove 142 of FIGS. 6 and 7 . The chemical liquid introduced into the inlet pipe 468 is discharged to the outlet pipe 478 as it is through the chemical liquid passage groove 142 . For example, at the beginning of the process of injecting Ringer's solution into a patient, when a user (such as a nurse or a doctor) places the knob 112 in the Open position, the drug will quickly enter the injection needle through the Ringer's solution tube.

Thereafter, by slightly linear movement of the knob 112 by the user, the wedge portion 114 for indicating the flow rate may be moved to the Close position of the flow rate display portion 432 . At this time, the ends of the inlet pipe 468 and the outlet pipe 478 are positioned at the chemical stopper 144 in the bottom 130 of the slide bar 100 . The chemical stopper 144 is a portion in close contact with the inlet pipe 468 and the outlet pipe 478, and the flow of the chemical is blocked.

That is, it is possible to reach an extremely short movement section and movement time from Open, where the liquid is completely circulated, to Close, where the distribution of the liquid is blocked.

When the user moves the knob 112 further in a straight line, the wedge portion 114 for indicating the flow rate will move to the position of the flow rate adjustment scale. At this time, the ends of the inlet pipe 468 and the outlet pipe 478 move from the bottom surface 130 of the slide bar 100 to the position of the pressure control wall 146 .

At this time, the pressure regulating wall 146 is formed to decrease in height toward the lower end of the slide bar 100 . Accordingly, as the slide bar 100 moves toward the tip, the communication space between the inlet pipe 468 and the outlet pipe 478 gradually expands, and the flow rate gradually increases.

Here, the chemical flow rate control device of the present invention provides a slide bar bottom structure as illustrated in FIGS. 6 and 7 for accurate flow rate control. A configuration for controlling the flow rate will be described with reference to FIGS. 6 and 7 .

A partition wall 134 for partitioning the chemical solution passage groove 142 , the chemical solution stop portion 144 , and the pressure control wall 146 is formed in the bottom portion 130 of the slide bar 100 . And a sealing fastening groove 132 is formed along the circumference of the partition wall 134 . The O-ring 200 illustrated in FIG. 5 is fastened to the sealing fastening groove 132 . The O-ring 200 functions to prevent the chemical solution from leaking out of the device and at the same time be supported between the slide bar 100 and the chemical solution flow rate control body 400 to maintain the assembled state.

6 and 7 , a flow rate control groove 148 is formed to a predetermined depth along the longitudinal central axis of the pressure control wall 146 . And a chemical liquid circulation passage 136 through which the chemical liquid is circulated is formed in communication with the flow rate control groove 148 along the circumference of the pressure control wall 146 .

The flow rate control groove 148 is a space through which the chemical solution flows when the inlet pipe 468 and the outlet pipe 478 move along the pressure control wall 146 , and the chemical solution flowing through the flow rate control groove 148 is circulated through the chemical solution. It circulates therein along passage 136 . As shown, the chemical liquid circulation passage 136 is formed in a U-shape along the circumference of the pressure control wall 146 , the base end of the slide bar 100 is closed, and the front end communicates with the flow rate control groove 148 . and a chemical liquid communication part 152 to be used. Furthermore, the chemical liquid communication part 152 is formed to have the same depth over the entire section.

Therefore, even when the communication space between the inlet pipe 468 and the outlet pipe 478 on the pressure control wall 146 is insignificant, the chemical liquid circulates inside through the chemical liquid circulation passage 136, so that a large pressure is applied to a specific area. It can be prevented from being applied, and it is possible to precisely control the micro flow rate.

Various modifications are possible within the scope of the invention disclosed above without detracting from the basic idea. That is, all of the above embodiments should be interpreted as illustrative and not restrictive. Therefore, the protection scope of the present invention should be determined according to the appended claims, not the above-described embodiments, and if the components defined in the appended claims are substituted with equivalents, it should be considered as belonging to the protection scope of the present invention.

100: slide bar 110: base plate
112: knob 114: wedge portion for flow indication
120: slide fastening part 122: locking protrusion
130: bottom portion 132: sealing fastening groove
134: partition wall 136: chemical liquid circulation passage
142: chemical liquid passage groove 144: chemical liquid stop part
146: pressure control wall 148: flow control groove
152: chemical liquid communication part 200: O-ring (O-ring)
300: inlet and outlet sealing 310: inlet line through hole
320: outflow line through hole 400: chemical liquid flow control body
410: body 412: inlet and outlet sealing seating groove
420: slide bar coupling surface 422: first guide hole
424: second guide hole 430: first side upper surface
432: flow rate display 440: second side upper surface
442: anti-slip unevenness 462: inlet line fastening part
464: first inlet line communicating part 466: second inlet line communicating part
468: inlet pipe 472: outlet line fastening part
474: first outflow line communicating part 476: second outflow line communicating part
478: Outflow pipe

Claims (8)

a chemical liquid flow control body having a chemical liquid inlet passage and a chemical liquid outlet passage at the bottom of the body, wherein a pair of guide holes are formed in both side portions of the body along the longitudinal direction;
Slide having a slide fastening part fastened to the guide hole in both lower sides of the base plate, a knob protruding from the upper part of the base plate, and a wedge part for indicating a flow rate extending from the knob and protruding in a wedge shape toward one side bar;
a chemical liquid passage groove which is concavely formed to connect the chemical liquid inlet passage and the chemical liquid outlet passage as it is at the proximal end of the bottom surface of the slide bar;
a chemical solution stopper disposed adjacent to the bottom end of the slide bar in the chemical solution passage groove and closing the chemical solution inlet passage and the chemical solution outlet passage; and
It has a shape extending from the chemical stopper toward the front end of the bottom surface of the slide bar, and the communication space between the chemical liquid inlet passage and the chemical liquid outlet passage expands toward the lower surface end of the slide bar, and toward the lower surface end of the slide bar The pressure control wall is formed to be low in height, and the flow rate control groove is formed to a predetermined depth along the central axis in the longitudinal direction.
includes,
A chemical liquid flow control device communicating with the flow control groove along a circumference of the pressure control wall to form a chemical liquid circulation passage through which the chemical liquid is circulated.
According to claim 1,
A flow rate display unit for displaying a flow rate corresponding to the flow rate indication wedge is formed on the upper surface of one side portion of the chemical liquid flow control body, and the flow rate display unit displays an open indication that the chemical liquid completely passes from the base end to the front end, distribution of the chemical solution A chemical liquid flow control device in which the closed lock mark and the flow rate adjustment scale mark indicating the chemical flow rate adjustment stage are sequentially displayed.
According to claim 1,
A partition wall for partitioning the chemical solution passage groove, the chemical solution stopper, and the pressure control wall is formed on the bottom surface of the slide bar, and an O-ring for blocking the outflow of the chemical solution to a sealing fastening groove formed along the circumference of the partition wall (O-ring) is a liquid flow control device that is fastened.
delete delete delete According to claim 1,
The chemical liquid circulation passage is formed in a U-shape along the circumference of the pressure control wall, the bottom surface of the slide bar is closed, and the front end is formed to communicate with the flow control groove.
8. The method of claim 7,
The chemical liquid circulation passage is a chemical liquid flow control device that is formed at the same depth.

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