KR101005294B1 - Feeding device for liquid food - Google Patents

Abstract

PURPOSE: A liquid food feeder is provided, which can inject liquid food automatically by the electrically controlled pressure. CONSTITUTION: A liquid food feeder comprises: a housing in which a receiving space filled with liquid food is prepared, a discharge hole is formed in the concave center of the lower part, and the top is opened; a cap combined with the opened top of the housing; a feeding portion(20) including a pressure unit discharging liquid food to the discharge hole by pressing the liquid food; a control box(90) which is connected to the feeding portion and in which a controller controlling the pressure unit is built in; and a interception unit(80) intercepting the liquid food exhausted to the feeding tube.

Description

Feeding device for liquid food

The present invention relates to a fluid supply device, and more particularly, to a supply device for automatically supplying water or fluid into the intestines of patients who can not chew or swallow food themselves.

Unconscious and impaired patients who are unable to chew or swallow food themselves have been offered intestinal feeding (e.g., stomach or duodenum) using fluid in addition to calorie supplementation by injection known as intravenous injection. .

Intestinal feeding inserts a feeding tube through the nasal cavity or mouth of the patient to the intestine, connects a syringe containing water or fluid to the feeding tube, and lifts the syringe up so that the fluid is fed into the intestine by gravity. In addition, the nurse or assistant pressurizes the syringe so that the fluid or fluid in the syringe can be supplied into the intestine.

Such a conventional method requires a lot of time to inject the formula because the nurse or guardian must inject the formula directly to the patient. In addition, there is a problem in that when the pressure applied to the syringe during the injection of the fluid can damage the esophageal mucosa of the patient. In addition, the nurse or guardian has to change the syringe several times to supply the fluid, and there may be a hygiene problem due to bacterial invasion by contact during replacement.

In order to improve this problem, there is a method of supplying a liquid by putting the liquid in a container such as a ringer solution pack and then suspending the ringer solution pack high, but in this case, due to the limitation of single use, it is not torn and used. Since it is not a fixed shape to stand up, there is considerable inconvenience in moving and hanging in a fixed manner.

Republic of Korea Utility Model No. 0309884 discloses a fluid supply container for patients.

The disclosed fluid feed container includes a cover having at least one connector formed on a side wall thereof; A nozzle having an upper end opening, an air intake port selectively communicating with a connector at the upper end, coupled to the cover, a discharge hole protruding from the lower end, and a nozzle detachably sealed to the discharge hole of the body and the body filled with a liquid therein. Consists of units.

However, the fluid supply container is formed in a cylindrical shape to maintain a fixed form compared to using the existing ringer solution pack somewhat uncomfortable, but the injection or injection of the fluid by the nurse or guardian by adjusting the area of the air intake The amount of air must be adjusted manually, so care must be taken while the nurse or guardian watches. Therefore, there is a problem that reduces the efficiency of nursing work due to waste of time.

In addition, it is difficult to control the supply time and the feed rate because the flow is injected by gravity by opening the air inlet, there is an inconvenience to close the air inlet again when the supply of the flow is complete.

In addition, when storing the refrigerator after completion of the fluid supply, there is a problem of sealing the discharge port of the body by separating the nozzle unit connected to the discharge port of the body and then combining a separate discharge preventing cap.

The present invention was created to improve the above problems, and can reduce the labor of nurses or guardians by automatically injecting the formula by the pressure that is controlled electronically, rather than flowing the formula down by gravity. The purpose is to provide a fluid feeder.

Another object of the present invention is to provide a fluid feeding device that can be precisely controlled the feeding speed and the feeding time of the liquid can be supplied to the characteristics of each patient and easy to use and store.

The fluid supply device of the present invention for achieving the above object is provided with an accommodation space therein so that the fluid is filled, the discharge hole is discharged to the discharge is formed on one side, the cap coupled to the open one side of the housing and A feeding unit including a pressurizing unit configured to pressurize the flow type by sliding a piston installed in the housing; A control box connected to the feeding part and configured to control the pressurizing unit; a control box installed in the discharge hole of the housing and connected to a feeding tube extending into the body and intermittent with a flow type discharged to the feeding tube; It is characterized by including;

The pressurizing unit is one end is supported on the cap and the other side is connected to the piston expandable and contractable corrugated tube, the connection hose for connecting the fluid inlet formed in the cap and the control box, and is installed in the control box And a pump for injecting fluid into the pleated tube through the connection hose under the control of the controller.

And a pressure sensor installed in the feeding part to detect a pressure inside the housing and output a signal to the controller, and the control box controls the controller when the signal output from the pressure sensor reaches a set value. It further comprises an alarm unit for generating a warning sound to the outside.

The pressure unit is supported by the cap is connected to the piston and characterized in that it is provided with an actuator for moving the piston under the control of the controller.

The intermittent portion is provided with a transfer pipe screwed to the discharge pipe formed in the discharge hole of the housing and the feed tube is detachably coupled to the end, and the opening and closing unit is installed in the transfer pipe to open and block the passage of the transfer pipe It is characterized by.

The intermittent part may further include a heating means for warming a flow type moving along the passage of the transfer pipe.

As described above, according to the present invention, it is possible to reduce the labor of the nurse or guardian by automatically injecting the formula by using the pressure unit controlled by the controller.

In addition, by uniformly controlling the injection rate of the air supplied to the corrugated tube can maintain the amount and speed of the discharged formula is uniform, it is possible to supply the formula according to the characteristics of each patient.

And by operating the opening and closing valve of the intermittent portion can easily open and close the discharge hole of the housing is very easy to store or move.

Hereinafter, a fluid supply apparatus according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in detail.

1 is an exploded perspective view showing a fluid supply apparatus according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing the inside of the feeding unit applied to Figure 1, Figure 3 is a schematic block diagram showing the fluid supply of Figure 1 to be.

The formula used in the description of the present invention is supplied to the intestine to supply nutrients and moisture to people who cannot chew or swallow food on their own, such as unconscious and unimpaired patients or gastrointestinal patients. It means food that can be eaten without chewing, such as soup, and contains water.

1 to 3, the fluid supply apparatus 10 of the present invention includes a feeding unit 20, a control box 90, and an intermittent unit 80.

The feeding part 20 includes a housing 21 in which a fluid is filled in the inside, a cap 25 coupled to the housing 21, and a pressurizing unit for pressurizing the fluid in the housing 21.

The housing 21 is formed with a receiving space 23 of a constant size so that the fluid can be filled therein. The receiving space 23 is preferably formed in a circular shape for sliding movement of the piston 33 to be described later. The appearance and size of the housing 21 can be adjusted appropriately. One side of the housing 21 is open and the other side has a closed cylindrical structure. In the example shown, the housing 21 is open at the top and closed at the bottom. The fluid is injected through one open side. The lower part of the housing 21 has a streamlined dome shape, and a discharge hole 24 through which a flow type is discharged is provided in the center. The discharge hole 22 is coupled to the discharge hole extending to a certain length. A thread is formed on the outer circumferential surface of the discharge pipe 22 so as to be coupled to and separated from the intermittent portion 80. Threads shown may be omitted.

The housing 21 may be formed of a material such as resin or glass, and in this case, it is preferable that the housing 21 is made of a material harmless to the human body. In addition, the housing 21 is preferably formed of a light-transmissive material so as to easily check the injection state of the flow type, the amount of the remaining flow type from the outside. For example, the housing 21 may be made of tempered glass having excellent durability and light transmittance.

The cap 25 is coupled to the open upper portion of the housing 21. The cap 25 serves to seal the receiving space 23 of the housing 21. Threads are formed on the inner circumferential surface of the cap 25, and threads corresponding to the threads of the cap 25 are formed on the outer circumferential surface of the housing 21. Thus, the housing 21 is screwed into the cap 25. Alternatively, the housing 21 and the cap 25 may have a structure in which a screw thread is not formed and the housing 21 is fitted to the cap 25 to be coupled. In this case, the cap 25 is formed of a flexible material capable of elastic deformation so that fluid does not leak from the coupling portion between the cap 25 and the housing 21.

The pressurizing unit pressurizes the flow type accommodated in the housing 21 to be discharged through the discharge hole 24. The pressurizing unit includes a piston 33 installed inside the housing 21, a corrugated tube 30 having one side supported by the cap 25 and the other side connected to the piston 33, a cap 25 and a control box ( 90 is provided with a connection hose 31 for connecting, and a pump 35 for injecting fluid into the corrugated tube 30 through the connection hose 31.

The piston 33 is inserted into the housing 21 through the open side of the housing 21. It is preferable that there is no space between the piston 33 and the inner surface of the housing 21 so that all of the flow can be discharged when the piston 33 descends. For this purpose, the piston 33 has a shape corresponding to the inner surface of the lower portion of the housing 21. In the example shown, the piston 33 has a dome shape that is convex downward. Since the piston 33 is in direct contact with the fluid, it is preferable that the piston 33 is made of a silicon material that is harmless to the human body. In a state where the edge of the piston 33 is in close contact with the inner circumferential surface of the housing 21, the piston 33 slides to pressurize the flow type. Of course, the sealing member is installed on the edge of the piston 33 to maintain the watertight.

The corrugated tube 30 has an upper end connected to a lower portion of the piston 33 and a lower end connected to a bottom surface of the cap 25. Therefore, a closed space is formed inside the corrugated tube 30 to accommodate a fluid for pressurizing the piston 33. The corrugated tube 30 has a conventional bellows-like structure in which a plurality of corrugations are formed up and down to expand and contract the closed space therein. The outer diameter of the corrugated tube 30 is formed smaller than the inner diameter of the housing 21. In the illustrated example, the lower portion of the cap 25, the corrugated tube 30 is coupled, the lower portion of the corrugated tube 30, the piston 33 is coupled. Therefore, in the present invention, the cap 25, the corrugated tube 30, and the piston 33 are unitized and integrally formed. The corrugated tube 30 is positioned inside the housing 21 in a state in which the cap 25 is mounted on the housing 21.

The connection hose 31 connects the fluid inlet 28 formed in the cap 25 with the pump 35. The fluid inlet 28 formed by penetrating the cap 25 up and down is in communication with the inner space of the corrugated tube 30. The fluid inlet 28 is formed by extending a predetermined length of the fluid inlet pipe 27. The connection hose 31 is inserted into the fluid injection pipe 27 and connected. Of course, the connection hose 31 may be firmly coupled to the fluid injection pipe 27 using a conventional fixing device so that the connection hose 31 does not come out of the fluid injection pipe 27 while the fluid is being supplied. In addition, the connection hose 31 may be directly inserted and coupled to the fluid inlet 28 while the fluid injection tube 27 is omitted.

A conventional air pump is used as the pump 35 for injecting fluid into the corrugated tube 30 through the connection hose 31. In the present embodiment, the fluid supplied into the corrugated tube 30 becomes air. In addition, the fluid supplied to the corrugated tube may be water, depending on the type of pump. The pump 35 is installed inside the control box 90. Therefore, the connection hose 31 connected to the cap 25 extends into the control box 90 and is connected to the discharge port of the pump 35. Unlike the above, the pump 35 may be supported by the cap 25 and installed inside the corrugated tube 30. In this case, the pump 35 is connected to the control box 90 by a wire. When the pump 35 is operated to inject air into the corrugated tube 30, the corrugated tube 30 expands and the corrugated tube 30 that expands pushes the piston 33 downward. Therefore, since the piston 33 moves and pressurizes the flow formula, the flow formula is discharged to the outside through the discharge hole 24.

On the other hand, a fluid discharge port (not shown) is formed in the cap 25 to contract the expanded corrugated tube 30 by injecting air therein, and a valve member 39 capable of opening and closing the fluid discharge port is provided at the fluid discharge port. Is installed. The type of valve member is not particularly limited as long as the fluid outlet can be opened and closed. In addition, by installing a solenoid valve can be operated by the control of the controller. Although not shown, a tension spring may be installed inside the corrugated tube 30 for easy shrinkage of the corrugated tube 30. The upper end of the tension spring is fixed to the bottom of the cap 25, the lower end is fixed to the upper piston 33. Therefore, when the fluid outlet is opened while the corrugated tube 30 is expanded, the air is discharged and the corrugated tube 30 is contracted to the state before the air is injected by the restoring force of the tension spring.

Control box 90 is made of a variety of components for the operation of the present invention is built in the interior of the case 91 forming the appearance. The case 91 includes a controller 100 for controlling the pump 35 and a power supply unit (not shown). The controller 100 uses a conventional CPU. The power supply unit supplies driving power for operating various components installed in the control box 90. As the power supply unit, a commercial power source can be used. In this case, a power cable extending from the outside is inserted into the case 91 and installed. Of course, the battery can be used as a power supply in addition to the commercial power supply.

Outside the case 91 is provided with a power switch 96 for applying power, a step control switch 97 and 98 for adjusting the air injection speed, and an operation unit 95 including a reset switch 99. Prepared. Each switch is provided with lamps 97 indicating whether the switch is operated. By adjusting the injection speed of the air supplied to the inside of the corrugated tube 30 according to the characteristics of each patient through the operation unit 95 can be properly controlled the discharge of the flow type. Next to the operation unit 95, a display unit 93 displaying various types of information is provided.

The intermittent part 80 is a transfer pipe 81 screwed to the discharge pipe 22 of the housing 21, and an opening / closing valve 85 installed at the transfer pipe 81 to open and block a passage of the transfer pipe 81. ). A conventional valve capable of opening and closing the passage with the on / off valve 85 is used. The on-off valve 85 is formed with a handle 87 to be manually operated. Unlike shown, the open / close valve 85 may be configured as an electromagnetic valve that is opened and closed by the control of the controller 100. Feed tube (5) is coupled to the end of the feed pipe (81). Preferably the feeding tube 5 is coupled to the transfer tube 81 detachably. The feeding tube 5 extends into the intestine through the nasal cavity or mouth of the patient, and means a feeding tube such as a conventional nasogastric tube.

If it needs to be stored in the refrigerator after supplying the liquid to the patient, the shut-off valve 85 is closed, and then the feeding tube 5 is removed and the feeding part 20 is kept in the refrigerator with the intermittent part 80 coupled. Can be. At this time, the connection hose 31 connected to the pump is also separated from the cap 25.

The intermittent portion may further include a heating means for warming the flow moving along the passage of the transfer pipe.

As shown in FIG. 6, a heating coil 151 wound around the outer circumferential surface of the transfer pipe 81 as a heating means is used. In addition, the outer side of the transfer tube 81 wound around the heat transfer coil 151 may cover the heat insulation cover 153 for heat insulation and protection of the coil. In this case, the connection socket 155 is installed at the end of the transfer pipe 81 may be connected to the feed tube (5).

Although not shown, the heat transfer coil 151 may be connected to a power source extending from the outside or connected to a power unit of the control box. In addition, in addition to the heat transfer coil 151, a heating element may be used as a heating means. For example, a planar heating element having an annular cross section to surround the outer circumferential surface of the transport tube 81 may be installed in the transport tube 81 to heat the transport tube.

Meanwhile, in the present invention, the pressure sensor 50 may be installed in the feeding unit 20. The pressure sensor 50 detects the pressure applied by the piston 33 to the flow type and outputs a signal to the controller 100. By the signal output from the pressure sensor 50, the controller 100 controls the pump 35 in real time to adjust the amount of air supplied to the corrugated tube (30). The pressure applied to the fluid by the pressure sensor 50 can be maintained uniformly.

Various known sensors may be used as the pressure sensor 50 for detecting the pressure applied by the piston 33 to the flow type. For example, a piezoresistive semiconductor element installed in the piston 33 may be used to be positioned inside the corrugated tube 30. In addition, it is of course possible to apply an air pressure sensor for detecting the pressure of the air inside the corrugated tube (30).

In addition, as shown in FIG. 5, when the signal output from the pressure sensor 50 reaches a set value, the alarm unit 110 generating an alarm sound to the outside under the control of the controller 100 includes a control box 90. Can be installed in more. The alarm unit 110 includes an alarm driving circuit and a speaker. The alarm unit 110 is to call a nurse or a guardian when all the fluid is discharged from the inside of the housing 21. The controller detects the reduced pressure value inside the housing 21 and generates a warning sound through the speaker. Let's do it. Although not shown, in addition to the control box 90 is provided with a transmitter to output a signal to the remote control station when the alarm occurs by wire or wireless to inform the nurse or guardian that all the fluid is discharged from the inside of the housing (21). The transmitter transmits a signal through the communication network according to the transmission signal of the controller 100. As a communication network, various known methods such as a wired or wireless communication network are applied.

Hereinafter, the operation of the fluid supply device 10 according to an embodiment of the present invention configured as described above will be briefly described.

First, a certain amount of fluid is filled in the accommodation space of the housing 21. Then, the cap 25 on which the piston 33 and the corrugated tube 30 are mounted is coupled to the upper portion of the housing 21. In this state, the feeding tube 5 extending into the intestine of the patient is connected to the transfer tube 81, and then the opening and closing valve 85 is operated to open the passage of the transfer tube 81. Then, by placing the power button 96 of the control box 90 in the on state, by operating the step control switch (97) (98) to select the air inlet flow rate so that the fluid can be discharged in accordance with the state of the pump ( 35) start up. As air is injected into the corrugated tube 30 at the appropriate speed selected, the piston 33 moves by the expansion of the corrugated tube to pressurize the flow. The fluid is discharged into the feeding tube 5 at a uniform speed through the discharge hole 24 and injected into the intestine of the patient.

When the fluid corresponding to the patient's intake is introduced into the intestine of the patient, the operation of the pump 35 is stopped by the control of the controller 100. The operation time of the pump 35 corresponding to the intake amount of the patient according to the air infusion rate is controlled by the controller 100. Thereafter, the pump 35 is periodically operated at a time set by the control of the controller 100 so that the fluid can be supplied to the patient. For example, if the nurse or guardian operates the operation unit 95 to set the time so that the fluid can be supplied every two hours, the controller 100 operates the pump 35 according to the input value. In addition, when all the fluids filled in the housing 21 are discharged, the controller 100 transmits a warning sound by a signal detected from the pressure sensor 50 to call a nurse or guardian.

On the other hand, the fluid supply apparatus according to another embodiment of the present invention is shown in Figs.

4 and 5, the housing 60 constituting the feeding unit 40 is composed of the first and second body 61, 65 has a structure that is mutually coupled and separated by the coupling means. In detail, a first body 61 having a discharge hole formed therein and having a receiving space filled therein, and a second coupled to an upper portion of the first body 61 and having an actuator for moving the piston 33 therein. It is made of a body (65).

The upper portion of the first body 61 has an open structure. The outer ring 70 is installed outside the first body 61. By such a ring it is possible to suspend or fix the housing 60 to the fixing device. The intermittent part 80 connected to the discharge hole of the first body 61 is the same as the above-described embodiment, and thus a detailed description thereof will be omitted. The first body 61 and the second body 65 may be formed by coating the surface of the coupling portion with a flexible material such as silicon so as to maintain the watertight when the mutual coupling. Hook 75 formed on an upper portion of the first body 61 as a coupling means for coupling the first and second bodies 61 and 65 to each other, and the hook 75 is provided below the second body 65. It consists of a clamp member 71 that can be coupled to and detached.

The air cylinder 41 is used as an actuator installed in the second body 71. The air cylinder 41 is fixedly installed on the bottom of the cap 25. The rod 45 of the air cylinder 41 is connected to the piston 33.

The pressurizing unit including the air cylinder 41 further includes a pump 35 installed in the control box 90, and a connection hose 31 connecting the air cylinder 41 and the discharge port of the pump 35. . Air is injected into the air port of the air cylinder 41 by the operation of the pump 35, and the cylinder 45 is operated by the injected air to move the piston 33 downward. The air injection port of the air cylinder 41 is connected to the air injection pipe 27 formed in the cap 25. The connection hose 31 is coupled to the air injection pipe 27. Although not shown, an air discharge port connected to the air discharge port of the air cylinder 41 is formed in the cap 25, and a valve is installed at the air discharge port.

In the above-described example, the pressure sensor may be installed between the rod and the piston of the air cylinder. In this case, a load cell may be used as the pressure sensor.

And while the air cylinder is described as an example in the above-described example, a general actuator for moving the piston up and down in addition to the air cylinder can be used as a matter of course. For example, an electric motor controlled by a controller may be used as the actuator. In this case, the electric motor is supported and installed on the bottom of the cap. And the pinion is installed on the rotating shaft of the electric motor, the rack engaged with the pinion can be connected to the piston.

In the above, the present invention has been described with reference to the embodiments shown in the drawings, which are merely exemplary and will be understood by those skilled in the art that various modifications and equivalent embodiments are possible.

Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

1 is an exploded perspective view showing a fluid supply apparatus according to an embodiment of the present invention,

2 is a cross-sectional view showing the inside of the feeding unit applied to FIG.

3 is a block diagram schematically showing the fluid supply device of FIG.

Figure 4 is an exploded perspective view showing a feeding unit applied to the fluid supply apparatus according to another embodiment of the present invention,

FIG. 5 is a block diagram schematically illustrating a fluid supply apparatus to which FIG. 4 is applied.

Figure 6 is a cross-sectional view showing the main part of the fluid supply apparatus according to another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

20: feeding part 21: housing

22: discharge pipe 25: cap

 30: corrugated tube 31: connecting hose

33: piston 80: intermittent portion

85: on-off valve 90: control box

Claims (6)

An accommodation space is provided therein so that the fluid can be filled, a discharge hole is formed in the center of the concave lower part, and the upper part of the housing is opened, a cap coupled to the open upper part of the housing, and installed inside the housing and in contact with the fluid. A feeding unit including a pressurizing unit configured to slide the piston formed to be convex downward so as to correspond to the shape of the lower inner surface of the housing to pressurize the flow type to discharge the flow type to the discharge hole; A control box connected to the feeding unit and having a controller for controlling the pressurizing unit; And an intermittent part connected to the feed tube extending into the body and connected to the discharge hole of the housing to control the flow of the discharge tube to the feed tube by opening and closing the discharge hole. The pressure unit is one side is supported by the cap and the other side is connected to the piston expandable and contractable corrugated tube, a fluid hose formed in the cap and a connection hose connecting the control box, the control box is installed in the A pump for injecting fluid into the pleated tube through the connection hose under the control of a controller, It is further provided with a pressure sensor installed in the feeding unit for detecting the pressure inside the housing and outputs a signal to the controller, The control box further includes an alarm unit for generating a warning sound to the outside under the control of the controller when the signal output from the pressure sensor reaches a set value, and a transmitter for transmitting a signal to a remote control station through a communication network. Floating feeder characterized by. delete delete An accommodation space is provided therein so that the fluid can be filled, a discharge hole is formed in the center of the concave lower part, and the upper part of the housing is opened, a cap coupled to the open upper part of the housing, and installed inside the housing and in contact with the fluid. A feeding unit including a pressurizing unit configured to slide the piston formed to be convex downward so as to correspond to the shape of the lower inner surface of the housing to pressurize the flow type to discharge the flow type to the discharge hole; A control box connected to the feeding unit and having a controller for controlling the pressurizing unit; And an intermittent part connected to the feed tube extending into the body and connected to the discharge hole of the housing to control the flow of the discharge tube to the feed tube by opening and closing the discharge hole. The pressurizing unit is supported by the cap is connected to the piston and is provided with an actuator for moving the piston by the control of the controller, It is further provided with a pressure sensor installed in the feeding unit for detecting the pressure inside the housing and outputs a signal to the controller, The control box further includes an alarm unit for generating a warning sound to the outside under the control of the controller when the signal output from the pressure sensor reaches a set value, and a transmitter for transmitting a signal to a remote control station through a communication network. Floating feeder characterized by. According to claim 1 or claim 4, wherein the intermittent portion is screwed to the discharge pipe formed in the discharge hole of the housing and the feed tube is coupled to the feed tube detachably at the end, and installed in the transfer pipe and the passage of the transfer pipe Floating device, characterized in that it comprises an on-off valve for opening and closing the. The fluid supply apparatus according to claim 5, wherein the intermittent part further comprises heating means for warming the fluid moving along the passage of the transport pipe.

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