KR102576361B1 - Water purifier apparatus for medical appliance - Google Patents

Abstract

The present invention relates to a medical device water purification device to solve the problems of prior inventions, and includes a storage tank 100 that temporarily stores fluid supplied from the outside; A heating unit 200 that supplies heat to the fluid delivered from the outside; a supply unit 300 that applies pressure to the heated water supplied with heat from the heating unit; a distribution unit 400 that receives heated water from the supply unit and selectively supplies the heated water to a plurality of medical devices; It is a water purification device for medical devices including.

Description

Water purifier apparatus for medical appliance}

The present invention relates to a device that purifies and resupplies fluid required by medical devices and passes heated water through the inner peripheral part of the pipe.

Patent Document 001 includes a moving tube that forms a movement path for water introduced from the outside and is equipped with a kidney dialysis machine at the rear end; A feed pump unit mounted on the front end of the moving pipe and maintaining the amount and pressure of water flowing in from the outside; a first pure water treatment unit mounted on a moving pipe to be located at the rear of the feed pump unit and primarily treating water passing through the feed pump unit; A reverse osmosis water purification unit mounted on a moving pipe to be located at the rear of the first pure water treatment unit and purifying water that has passed through the first pure water treatment unit according to the reverse osmosis principle; a second pure water treatment unit mounted on a moving pipe to be disposed between the reverse osmosis water purification unit and the renal dialysis machine, and subsequently treating the water that has passed through the reverse osmosis water purification unit into pure water; It presents a technology related to a kidney dialysis water production device and a kidney dialysis water production method including.

Patent document 002 is a centralized dialysate management system that mixes and stores dialysate powder and pure water into hemodialysis solutions A and B and supplies them to artificial kidney machines along the piping section of multiple artificial kidney rooms; The transfer pump formed on one side of the storage tank output of the dialysate central management system delivers hemodialysis solution A, B and alkaline ionized water for disinfection to the artificial kidney device connection device along the hemodialysis solution A pipe and the hemodialysis solution B pipe or complete disinfection. a piping unit that drains the alkaline ionized water along the drain pipe; An artificial kidney device connecting device that is connected to the hemodialysis solution A pipe, the hemodialysis solution B pipe, and the drain pipe of the piping section that flows into the artificial kidney room, and supplies hemodialysis solution to the artificial kidney by controlling the pressure and flow rate, and self-disinfects the supply tube. ; It presents technology regarding a hemodialysate supply device for artificial kidney devices, including:

Patent document 003 is a pressurized pump provided with a water supply pipe on one side and circulating external water into the case through the water supply pipe; A filter housing connected to a pressurized pump and primarily filtering large particle foreign substances contained in water circulated through the pressurized pump; A fine manure filter connected to the filter housing and filtering medium particle foreign substances from the foreign substances primarily filtered in the filter housing; A membrane filter connected to the fine manure filter and filtering fine particles of foreign matter from the secondarily filtered foreign matter in the fine manure filter; A cold and hot water supply pipe connected to the membrane filter and supplying water filtered by the membrane filter to an external cold and hot water machine; A disinfectant tank in which a certain amount of disinfectant solution is stored; A suction pump connected to the disinfectant tank and quantitatively suctioning the disinfectant solution stored in the disinfectant tank by a pump timer that operates at a preset time; A mixer in which a suction pump and a membrane filter are connected to one side and the other side to mix the disinfectant solution of the suction pump and the filtered water of the membrane filter to disinfect medical devices and medical pipes deposited by bacteria; A supply pipe connected to the mixer to supply disinfectant solution and filtered water to the medical device; A pressure tank connected to the supply pipe and supplying the necessary amount of water to supplement when the amount of disinfectant and water supplied through the supply pipe is insufficient than the preset amount; A display unit provided on one side of the upper part of the case to display the operating status inside; It presents technology related to water purification devices for disinfecting dental medical pipes and dental medical devices, including.

Patent Document 004 includes a wall-mountable case equipped with a multi-stage filtration means and a pressurizing device; a storage means connected to a water purification means to store discharged purified water; Supply means for supplying stored purified water at a constant pressure; It presents technology for a wall-mounted automatic purified water supply device for dental hospitals.

KR 10-1012194 B1 (January 25, 2011) KR 10-0656537 B1 (December 5, 2006) KR 10-2008-0078171 A (August 27, 2008) KR 20-0246990 Y1 (September 5, 2001)

The purpose of the present invention is to purify and re-supply the fluid required by medical devices and to pass heated water through the inner peripheral part of the pipe.

The present invention relates to a medical device water purification device to solve the problems of prior inventions, and includes a storage tank 100 that temporarily stores fluid supplied from the outside; A heating unit 200 that supplies heat to the fluid delivered from the outside; a supply unit 300 that applies pressure to the heated water supplied with heat from the heating unit; a distribution unit 400 that receives heated water from the supply unit and selectively supplies the heated water to a plurality of medical devices; Includes.

The distribution unit 400 of the present invention includes a main supply pipe 410 that receives heated water from the supply unit 300; A plurality of branch pipes 420 branched from the main supply pipe 410 and through which heated water passes inward along the longitudinal direction; A connector 430 whose one end is connected to and communicates with the central portion of each branch pipe and whose other end is connected to each medical device; Includes.

The present invention includes a flow rate control unit 500 that controls the flow rate value through which heated water passes; Includes.

The main supply pipe 410 of the present invention is formed in plural, and the flow rate value of the heated water passing through each main supply pipe 410 is formed in a structure that is the same.

The flow control unit 500 of the present invention is formed in a structure disposed within each of the main supply pipes 410.

The heating unit 200 of the present invention includes a reservoir heating unit 210 that supplies heat to the fluid contained in the reservoir 100; A circulation heating unit 220 that supplies heat to the fluid flowing out of the storage tank 100; Includes.

The storage tank heating unit 210 of the present invention includes a first storage tank heating unit 211 whose heating part is in contact with the fluid in the storage tank 100; a second storage tank heating unit 212 disposed within the storage tank 100 and including a transfer unit 212-1 in which a heating element circulates at a constant speed; Includes.

The present invention includes a purification unit 600 that performs a purification process on a fluid and supplies it to the storage tank 100; Includes.

Thanks to the present invention, foreign substances adhering to the inner periphery of the fluid flow path supplied to the medical device can be efficiently removed.

In addition, by minimizing the section where the heated water supplied with heat by the heating unit does not pass, it is possible to prevent the phenomenon of some contaminated fluid being unintentionally supplied to the medical device.

1 is a conceptual diagram showing one embodiment of the present invention.
Figure 2 is an exemplary diagram showing a circulation heating unit of the present invention.
Figure 3 is an exemplary diagram showing a storage tank heating unit of the present invention.
Figure 4 is an exemplary diagram showing the supply unit of the present invention.
Figure 5 is an exemplary diagram showing one embodiment of the distribution unit of the present invention.
Figure 6 is an exemplary diagram showing a plurality of other embodiments according to the distribution unit of the present invention.
Figure 7 is an exemplary diagram showing a plurality of embodiments according to the flow rate control unit of the present invention.
Figure 8 is a conceptual diagram showing another embodiment of the present invention.

Hereinafter, the most preferred embodiments of the present invention will be described in detail in order to enable those skilled in the art to easily practice the present invention.

Numbers cited in the examples below are not limited to the objects of citation and can be applied to all examples. An object that has the same purpose and effect as the configuration presented in the examples is an equivalent replacement object. The high-level concept presented in the examples includes low-level concept objects that are not described.

(Example 1-1) The present invention relates to a device for supplying heated water to a plurality of medical devices, comprising: a reservoir 100 that temporarily stores fluid supplied from the outside; A heating unit 200 that supplies heat to the fluid delivered from the outside; a supply unit 300 that applies pressure to the heated water supplied with heat from the heating unit; a distribution unit 400 that receives heated water from the supply unit and selectively supplies the heated water to a plurality of medical devices; Includes.

In general, a medical device refers to a product used for the purpose of diagnosing, treating, or preventing disease, or to diagnose or treat injury or disability. Representative examples include surgical and surgical equipment that cleans by periodically repeating suction and irrigation, and maintenance equipment that periodically injects and intentionally expels specific fluids into the human body. All of the above-mentioned devices are characterized by the fact that they use a fluid with a constant velocity value, and in order to implement this, the operator or manager periodically injects fluid into the above-mentioned devices.

Due to the functional characteristics of fluids that come into physical contact with organs within the human body, fluids used in medical devices must meet certain cleanliness values. Therefore, it is common for medical devices to be equipped with a separate water purification process. At this time, the fluid injected into the medical device from the outside contains a large amount of microorganisms, which adhere to the inside of the pipe connected between the plurality of components. Microorganisms adhering to the inner periphery of the pipe decompose over time, and fluid that meets the cleanliness value before being introduced into the medical device may become partially contaminated and come into contact with the human body. Accordingly, the present invention is formed with a structure including a heating unit 200 that heats a fluid that is temporarily accommodated in a storage tank and satisfies a certain cleanliness value and transfers the heated water into the pipe.

(Example 1-2) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 1-1, one end of the supply unit 300 is coupled to the storage tank 100, The other end is formed in a structure that is coupled to the distribution part 400.

(Example 1-3) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 1-2, the supply unit 300 includes the storage tank 100 and the distribution unit 400. A plurality of pumps 310 arranged in parallel therebetween; Includes. The supply unit 300 supplies heated water to the distribution unit 400, which distributes fresh water to a plurality of medical devices. Accordingly, the supply unit 300 is formed in a structure disposed between the storage tank 100 that receives fluid from the outside and the distribution unit 400 that distributes the fluid to a plurality of medical devices.

In order to implement the above-described technology, the supply unit 300 may be formed in a structure including a pump 310 in which the reservoir 100 is coupled to one end and the distribution unit 400 is coupled to the other end. That is, the pump 310 can supply fluid that satisfies the cleanliness value to a plurality of medical devices by applying pressure from one end to the other end. At this time, due to the nature of the function of always receiving fluid when the medical device is operating, the pump 310 constituting the supply unit 300 has a structure in which a plurality of first pumps 311 and second pumps 312 are arranged in parallel. can be formed. That is, when a problem occurs in any pump, another pump can be operated to prevent unintentional failure of fluid supply to the medical device.

(Example 1-4) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 1-1, one end is coupled to the supply part 300, and a micro filter is disposed in the central part. filtration unit; Includes.

(Example 1-5) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 1-1, it is disposed between the supply unit 300 and the distribution unit 400, A sterilization unit that performs a sterilization process on heated water; Includes.

(Example 1-6) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 1-5, the sterilizing unit includes: UV irradiation means for irradiating ultraviolet rays to the internal fluid; Includes.

According to the present invention, a separate purification process is arranged between the supply unit 300 and the distribution unit 400, so that a separate purification process can be performed on the fluid contained in the storage tank 100. At this time, between the supply unit 300 and the distribution unit 400, a structure may be formed including a filtration unit including a micro filter disposed on a passage through which the fluid passes, and a sterilization unit that performs a sterilization process on the fluid. As the sterilizing unit is formed with a structure including a UV irradiation means that irradiates ultraviolet rays to the inner periphery of the flow path, microorganisms present in the fluid can be continuously removed.

As designed with the above structure, the present invention can transfer the fluid supplied from the storage tank 100 into the medical device while maintaining a constant cleanliness value.

(Example 2-1) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 1-1, the distribution unit 400 supplies heated water from the supply unit 300. Receiving main supply pipe (410); A plurality of branch pipes 420 branched from the main supply pipe and through which heated water penetrates the inside along the longitudinal direction; A connector 430 whose one end is connected to and communicates with the central portion of each branch pipe and whose other end is connected to each medical device; Includes.

The distribution unit 400 supplies the fluid received from the supply unit 300 to a plurality of medical devices. Accordingly, the distribution unit 400 may be formed in a structure that is coupled to the other end of the supply unit 300. As the present invention is formed with a structure including the distribution unit 400, the present invention must be able to simultaneously supply fluid to a plurality of medical devices.

In order to implement the above structure, the distribution unit 400 includes a main supply pipe 410 with one end in communication with the supply unit 300, a plurality of branch pipes 420 with one end in communication with the main supply pipe 410, and It may be formed in a structure that is coupled to a plurality of branch pipes 420 and includes a connector 430 whose other end is coupled to a medical device.

(Example 2-2) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 2-1, the connector 430 has a structure branched from the central portion in the longitudinal direction. is formed by

(Example 2-3) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 2-2, one end of the connector 430 communicates with the inside of the branch pipe 420. an inlet 431 through which heated water flows into the inside; A circulation port 432 that communicates with the inlet 431 and re-supplies heated water to the branch pipe 420; Includes.

The connector 430 is configured to receive fluid from the branch pipe 420 in communication with the main supply pipe 410 and deliver it to a medical device coupled to the other end. In other words, the connector 430 performs a mediator function to inject the fluid transferred from the main supply pipe 410 to the branch pipe 420 into the medical device. At this time, in a situation where power is not applied to the medical device coupled to the connector 430, the fluid supplied from the branch pipe 420 to the connector 430 must be reintroduced into the main supply pipe 410. That is, a path is formed to discharge the fluid flowing into the medical device, thereby reducing the pressure of the fluid applied to the medical device, and at the same time, power is applied to circulate the fluid to other medical devices that consume the fluid.

In this way, in order to implement selective fluid supply of the connector 430, one end of the connector 430 extends from the inlet 431 and the inlet 431 that receives fluid from the branch pipe 420 to connect the branch pipe 420. ) may be formed in a structure including a circulation port 432 that re-supplies fluid. That is, it is formed in a structure that starts from the central part and branches from the other end to one end, so that the above-described technology can be implemented. In addition, by minimizing the section where heated water is not transported to remove microorganisms adhering to the inner periphery of the pipe, the cleanliness of the fluid later introduced into the medical device can be efficiently maintained.

(Example 2-4) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 2-3, the branch pipe 420 has one end communicating with the main supply pipe 410. a first branch pipe 421 whose other end is coupled to the inlet 431; a second branch pipe 422, one end of which is coupled to the circulation port 422, and the other end of which communicates with the main supply pipe 410; Includes.

(Example 2-5) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 2-4, the other end of the first branch pipe 421 and the second branch pipe One end of 422 is formed in a structure exposed to the outside.

The connector 430 is configured to be connected to the branch pipe 420 in communication with the main supply pipe 410, and serves as a medium for supplying fluid to a medical device connected to the other end. At this time, if the inlet 431 and the circulation port 432 of the connector 430 are formed in a structure in which they communicate from the central part of one branch pipe 420, the fluid flows through both the branch pipe 420 and the connector 430. As it penetrates, the problem arises that the flow rate of the fluid flowing into the medical device is reduced.

In order to solve the above problem, the branch pipe 420 is formed into a structure including a first branch pipe 421 coupled to the inlet 431 and a second branch pipe 422 coupled to the circulation port 432. Thus, the path through which fluid is transferred from the branch pipe 420 can be limited to a structure that only passes through the connector 430. At this time, as the ends of the plurality of branch pipes 421 and 422 coupled to the connector 430 are formed in a structure exposed to the outside, the reaching distance from the other end of the connector 430 to the location where the medical device is placed can be minimized. You can. That is, by maximizing the section in which the heated water whose temperature value has risen by the heating unit 200 circulates, the cleanliness of the fluid ultimately introduced into the medical device can be efficiently maintained.

(Example 3-1) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 2-1, the present invention includes a flow rate control unit 500 that controls the flow rate value through which heated water passes; Includes.

(Example 3-2) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 3-1, the flow rate control unit 500 is disposed on the inner periphery of the main supply pipe 410. a first flow rate control unit 510; Includes.

(Example 3-3) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 3-2, the first flow rate control unit 510 is located on the inner periphery of the main supply pipe 410. An orifice that varies the diameter value of; Includes.

The present invention is a device that injects a fluid that satisfies a certain cleanliness value into a medical device and at the same time circulates heated water to remove microorganisms adhering to the inner periphery of the pipe. At this time, each medical device receives the fluid it needs as the flow rate is distributed by the distribution unit 400.

Due to the structural characteristics of the distribution unit 400 including the main supply pipe 410 and the branch pipe 420, the branch pipe 420 branched from the main supply pipe 410 is structured so that no fluid of the required flow rate is input. Problems may arise. Accordingly, the main supply pipe 410 may be formed in a structure in which the first flow rate control unit 510 is disposed to adjust the diameter value of the inner peripheral portion through which the fluid passes. That is, as the diameter value of the main supply pipe 410 is reduced, the first flow control unit 510 can efficiently supply fluid to the branch pipe 420 branching from the main supply pipe 410. At this time, the structure or shape of the first flow control unit 510 is not specifically limited, but an orifice is disposed on the inner periphery of the main supply pipe 410 and can easily change the diameter value for the cross-sectional area of the flow path. It is preferable that it be formed in a structure containing.

(Example 3-4) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 3-3, whether or not the medical device coupled to the other end of the connector 430 operates is determined. A power detection unit that recognizes; Includes.

(Example 3-5) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 3-4, the first flow control unit 510 is structured to be interlocked with the power detection unit. is formed by

The first flow control unit 510 disposed on the inner periphery of the main supply pipe 410 changes the diameter value of the cross-sectional area of the passage through which the fluid passes depending on the situation, and the supply unit 300 is a branch pipe that supplies fluid to the medical device. Fluid can be continuously supplied to (420). At this time, the present invention is formed with a structure including a power detection unit that recognizes whether each medical device coupled to the connector 430 is operating, and at the same time, a first flow rate control unit 510 that controls the diameter value of the main supply pipe 410. ) may be formed in a structure that is interlocked with the power detection unit. That is, the first flow control unit 510 selectively changes the diameter value of the main supply pipe 410 based on the signal received from the power detection unit, thereby keeping the flow rate input into the branch pipe 420 constant. The value can be maintained.

(Example 4-1) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 3-1, the main supply pipe 410 is formed in plural, each main supply pipe ( 410) The flow rate value of the heated water penetrating the inside is formed in a structure that is the same.

The distribution unit 400 is configured to transfer the fluid or heated water supplied from the supply unit 300 to the inner peripheral part of the pipe coupled with each medical device. At this time, the branch pipe 420 branched from the main supply pipe 410 that receives fluid or heated water from the supply unit 300 and the connector 430 that delivers fluid or heated water to the medical device are connected to one main supply pipe 410. ), a problem may arise that the flow rate values supplied to the plurality of medical devices are formed differently.

In order to solve the above problem, the main supply pipe 410, which supplies fluid or heated water to the branch pipe 420 and the connector 430, is formed in a structure in which it branches into multiple branches from the pipe communicating with the supply unit 300. , the flow rate values measured within each main supply pipe 410 can be made identical.

(Example 4-2) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 4-1, the main supply pipe 410 is connected to the supply unit 300 and the storage tank 100. ) a plurality of first main supply pipes 411 disposed between; Includes.

(Example 4-3) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 4-2, the first main supply pipe 411 has a longitudinal central portion formed by the branch pipe ( a plurality of second main supply pipes 412 communicating with 420) and having one end and the other end communicating with the plurality of first main supply pipes 411; Includes.

(Example 4-4) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 4-3, each of the second main supply pipes 412 supplies heating to one medical device. It is formed in a structure that supplies water.

The branch pipe 420 and connector 430 that supply fluid or heated water to the medical device receive fluid or heated water from the main supply pipe 410 that communicates with the supply unit 300. At this time, the main supply pipe 410 is branched from a pipe communicating with the supply unit 300 and is formed in a structure in which a plurality of lines are arranged in parallel, so that the flow rate value of the fluid or heated water injected into each main supply pipe 410 is the same. It can be maintained.

In order to implement the above structure, the main supply pipe 410 communicates with the supply unit 300 to receive fluid, and communicates with the storage tank 100 to transfer the circulated fluid back to the storage tank 100. It may be formed in a structure including a supply pipe 411 and a plurality of second main supply pipes 412 whose longitudinal ends are in communication with the plurality of first main supply pipes 411. In other words, as the flow rate value of the fluid or heated water passing through each second main supply pipe 412 is formed at a constant value, it is possible to prevent the phenomenon of unintentionally measuring a flow rate below the required value to the medical device. . At this time, one connector 430 may be coupled to each second main supply pipe 412. By designing the structure as described above, the flow rate values input to each of the plurality of medical devices can all be kept constant.

(Example 5-1) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 4-1, the flow rate control unit 500 is disposed within each of the main supply pipes 410. It is formed into a structure that is

(Example 5-2) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 5-1, the first main supply pipe 411 and the second main supply pipe 412 a second flow control unit disposed at the intersection point; Includes.

The flow control unit 500 is configured to smoothly supply fluid or heated water to the branch pipe 420 that communicates with the main supply pipe 410. Accordingly, the flow control unit 500 may be formed in a structure disposed within the main supply pipe 410 in order to vary the diameter value of the flow path within the main supply pipe 410. At this time, the flow control unit 500 may be formed in a structure including a second flow control unit disposed at a point where the first main supply pipe 411 and the second main supply pipe 412 intersect each other. That is, as the second flow control unit is disposed in the section branching from the first main supply pipe 411 that receives the entire amount of fluid or heated water from the supply unit 300, the manager passes through each second main supply pipe 412. The flow rate value of the fluid or heated water can be easily controlled. In addition, the structure or shape of the second flow rate control unit is not specifically limited, but, like the first flow control part 510, it is preferably formed to include an orifice that changes the diameter value of the flow path.

(Example 5-3) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 5-2, whether or not the medical device in communication with the second main supply pipe 412 operates is determined. A power detection unit that recognizes; Includes.

(Example 5-4) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 5-3, the second flow rate control unit is formed in a structure interlocked with the power detection unit. .

The second flow rate control unit disposed at the point where the first main supply pipe 411 and the second main supply pipe 412 intersect each other changes the diameter value of the cross-sectional area of the flow path through which the fluid passes depending on the situation, so that each second The same value of flow rate can be continuously supplied to the main supply pipe 412. At this time, the present invention is formed with a structure that includes a power detection unit that recognizes whether each medical device coupled to the connector 430 is operating, and at the same time, the second flow control unit that controls the diameter value is linked to the power detection unit. It can be formed as That is, the second flow rate control unit can always maintain the flow rate input into the second main supply pipe 412 at a constant value based on the signal received from the power detection unit.

(Example 6-1) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 1-1, the heating unit 200 adds heat to the fluid contained in the storage tank 100. A storage tank heating unit 210 that supplies; A circulation heating unit 220 that supplies heat to the fluid flowing out of the storage tank 100; Includes.

The heating unit 200 is configured to generate heated water by supplying heat to the fluid in the storage tank 100 supplied from the outside. At this time, the heating unit 200 will be formed in a structure including a storage tank heating unit 210 disposed in the storage tank 100 and a circulation heating unit 220 that separately supplies heat to the fluid flowing out of the storage tank 100. You can. At this time, as the circulation heating unit 220 is formed in a structure disposed between the storage tank 100 and the supply unit 300, the supply unit 300 receives heated water for which the supply of heat has been completed. In addition, the circulation heating unit 220 forms a separate flow path that selectively circulates between the storage tank 100 and the supply unit 300, so that the fluid flowing out of the storage tank 100 selectively circulates through the circulation heating unit 220. Additional calories can be supplied by passing through.

As the structure includes the circulation heating unit 220, which provides heat by circulating fluid even outside the storage tank 100, the manager can shorten the time required for the heated water to reach a specific temperature within the system. .

(Example 6-2) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 6-1, the circulation heating unit 220 is an inner peripheral part of a pipe through which fluid is transferred. A circulation heating portion 221 formed on the outer periphery and supplying heat to the inside of the pipe; Includes.

(Example 6-3) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 6-2, the circulation heating unit 220 is connected to the circulation heating unit 221. a plurality of first electrodes 222 that selectively activate the circulation heating unit 221; Includes.

The circulation heating unit 220 is configured to supply additional heat to the fluid flowing out of the storage tank 100, and may be formed in a structure disposed between the storage tank 100 and the supply unit 300. In order to supply heat to the fluid penetrating the inside of the transfer pipe, the circulation heating unit 220 is connected to the circulation heating unit 221 and the circulation heating unit 221 formed in a shape surrounding the outer periphery of the transfer pipe to apply power. It may be formed in a structure including a plurality of electrodes 222. That is, as the plurality of electrodes 222 apply electrodes to the circulation heating unit 221, the circulation heating unit 221 is sequentially activated to supply heat to the fluid circulating around the inner periphery of the transfer pipe.

(Example 6-4) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 6-3, the circulation heating unit 220 is connected to the circulation heating unit 221. a first temperature detection unit 710 that measures temperature values in real time; Includes.

(Example 6-5) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 6-4, the circulation heating unit 220 is disposed on the inner periphery of the pipe through which fluid is transferred. a third flow rate control unit 520 that controls the diameter value of the fluid transfer path; Includes.

(Example 6-6) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 6-5, the third flow rate control unit 520 is connected to the first temperature sensor 710. ) is formed in a structure that is interlocked with.

The circulation heating unit 220 has a first temperature sensor 710 that measures the temperature value of the circulation heating unit 221, and the plurality of electrodes 222 organically detect the amount of power applied to the circulation heating unit 221. You can control it. In addition, due to the structural characteristics of the circulation heating unit 220, which supplies heat to a fluid with a constant flow rate, a third flow rate control unit 520 is installed to control the flow rate value of the fluid for the section where the circulation heating unit 220 is placed. Can be placed additionally. At this time, the third flow control unit 520 is formed in a structure interlocked with the first temperature detection unit 710, and dependently controls the flow rate value of the fluid based on the heat value supplied from the circulation heating unit 220. can do.

(Example 7-1) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 6-1, the storage tank heating unit 210 is a heating unit that heats the fluid in the storage tank 100. A first storage tank heating unit 211 in contact with; a second storage tank heating unit 212 disposed within the storage tank 100 and including a transfer unit 212-1 in which a heating element circulates at a constant speed; Includes.

(Example 7-2) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 7-1, the first storage tank heating unit 211 is installed within the storage tank 100. A first storage heating unit 211-1 formed in a structure that protrudes from the main part at a predetermined height; Includes.

The storage tank heating unit 210 is configured to supply heat to the fluid temporarily accommodated in the storage tank 100. Therefore, heated water can be continuously supplied to the supply unit 300 in communication with the storage tank 100. At this time, the storage tank heating unit 210 is in contact with the fluid in the storage tank 100, and the first storage tank heating unit 211, which directly supplies heat to the fluid, and the system in which the heat medium continuously circulates inside are in contact with the fluid. It may be formed in a structure including a second storage tank heating unit 212.

By designing the above structure, the manager can secure heated water at a temperature that satisfies the set value in a short period of time and at the same time prevent the phenomenon of the temperature of the heated water decreasing over time.

(Example 7-3) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 7-2, the storage tank 100 is a device disposed inside to temporarily store fluid. 2 temperature detection unit 720; Includes.

(Example 7-4) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 7-2, the storage tank heating unit 211 is connected to the second temperature sensing unit 720. A second electrode (211-2) that is linked with and selectively activates the first storage heating unit (211-1); Includes.

The storage tank heating unit 210 is configured to supply heat to the fluid in the storage tank 100 supplied from the outside and temporarily accommodated inside, and is a first storage tank heating section that directly contacts and heats the fluid in the storage tank 100 ( 211) and a system in which a heat medium that supplies heat continuously circulates includes a second reservoir heating unit 212 that supplies heat by contacting a fluid.

The first storage tank heating unit 211 has the advantage of being able to increase the temperature value of the fluid contained in the storage tank 100 in a short time due to the structural characteristics of the first storage heating unit 211-1 in contact with the fluid. However, it is difficult to supply heat to maintain a constant temperature value, so overheating of the fluid in the storage tank 100 may occur.

In order to solve the above problem, the present invention may additionally include a second temperature sensor 720 disposed in the storage tank 100 to measure the temperature value of the fluid in real time. At this time, the second temperature sensing unit 720 is formed in a structure that is interlocked with the first storage tank heating unit 210, and supplies power to the first storage heating unit 211-1 when the temperature exceeds the set value is measured. The power supply path to the applied second electrode 211-2 is blocked. That is, as only the second storage tank heating unit 212 is maintained in an activated state, the fluid in the storage tank 100 is not overheated and a constant temperature value can be maintained.

(Example 8-1) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 1-1, a purification process is performed on the fluid and the purification is supplied to the storage tank 100. Wealth (600); Includes.

(Example 8-2) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 8-1, the purification unit 600 removes foreign substances from the fluid supplied from the outside. Filtration unit (610); an ionization unit 620 that softens the fluid supplied from the filtration unit 610; a deodorizing unit 630 that performs a deodorizing process on the fluid supplied from the ionization unit 620; Includes.

The present invention is a device for supplying a fluid that satisfies a certain cleanliness value to a plurality of medical devices, and can be formed with a structure including a purification unit 600 that performs a purification process on the fluid supplied into the storage tank 100. there is. At this time, the purification unit 600 includes a filtration unit 610 in which a sand filter made of a large amount of quartzite, silica sand, and coke is disposed, and an ionization unit that softens the fluid by removing positive ions such as calcium and magnesium remaining in the fluid. The unit 620 and a deodorizing unit 630 in which one or more carbon filters are disposed may be formed in a structure in which the deodorizing unit 630 is sequentially disposed. That is, as the purification process is performed on the fluid before being introduced into the storage tank 100, the cleanliness value of the fluid being introduced into the medical device can be efficiently met.

(Example 8-3) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 8-1, the purification unit 600 is a water treatment unit that processes fluid supplied from the outside. (640); Includes.

(Example 8-4) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 8-3, the water treatment unit 640 includes at least one nanofilter disposed therein; Includes.

(Example 8-5) The present invention relates to a device for supplying heated water to a plurality of medical devices. In Example 8-3, the water treatment unit 640 is a contamination sensor that measures the contamination level of the fluid in real time. ; Includes.

The purification unit 600, which performs a purification process on the fluid supplied into the storage tank 100, includes a water treatment unit 640 in which one or more nanofilters are formed of a semi-permeable membrane and are disposed therein to purify the fluid by reverse osmosis. It can be formed into a structure that does. That is, impurities are removed from the fluid by reverse osmosis filtration performed by the nano filter, and clean fluid is introduced into the storage tank 100. At this time, a pollution sensor that measures the pollution level of the fluid in real time may be placed inside the water treatment unit 640.

10: Medical device 100: Storage tank
200: heating unit
210: storage tank heating unit 211: first storage tank heating unit
211-1: storage heating unit 211-2: second electrode
212: Second storage tank heating unit
220: circulation heating unit 221: circulation heating unit
222: first electrode
300: supply unit 310: pump
400: distribution unit
410: main supply pipe 411: first main supply pipe
412: second main supply pipe 420: branch pipe
421: first branch pipe 422: second branch pipe
430: Connector 431: Inlet
432: circulation area
500: flow control unit 510: first flow control unit
520: Third flow control unit
600: purification unit 610: filtration unit
620: Ionization unit 630: Deodorization unit
640: Water treatment department
710: first temperature sensor 720: second temperature sensor

Claims (8)

In a device for supplying heated water to a plurality of medical devices,
A storage tank 100 that temporarily stores fluid supplied from the outside;
A heating unit 200 that supplies heat to the fluid delivered from the outside;
a supply unit 300 that applies pressure to the heated water supplied with heat from the heating unit 200;
a distribution unit 400 that receives heated water from the supply unit 300 and selectively supplies the heated water to a plurality of medical devices; and
It includes a flow rate control unit 500 that controls the flow rate value through which the heated water passes,
The distribution unit 400,
A main supply pipe 410 that receives heated water from the supply unit 300;
A plurality of branch pipes 420 branched from the main supply pipe 410 and through which heated water flows inward along the longitudinal direction;
It includes a connector 430, one end of which is connected to and connected to the central part of each branch pipe 420, and the other end of which is connected to each medical device,
The connector 430 is formed in a branched structure starting from the central part along the longitudinal direction,
One end of the connector 430 is in communication with the inside of the branch pipe 420, and has an inlet 431 through which heated water flows into the inside; It includes a circulation port 432 that communicates with the inlet 431 and re-supplies heated water to the branch pipe 420,
The flow control unit 500 is a water purification device for a medical device including a first flow control unit 510 disposed on an inner peripheral portion of the main supply pipe 410.
delete delete In claim 1,
The main supply pipe 410 is,
A water purification device for medical devices that is formed in a plurality, and is formed in a structure in which the flow rate value of the heated water passing through each main supply pipe (410) is the same.
In claim 4,
The flow control unit 500,
A water purification device for medical devices formed in a structure disposed within each of the main supply pipes (410).
In claim 1,
The heating unit 200,
A storage tank heater 210 that supplies heat to the fluid contained in the storage tank 100;
A circulation heating unit 220 that supplies heat to the fluid flowing out of the storage tank 100; A water purification device for medical devices including.
In claim 6,
The storage tank heating unit 210,
a first storage tank heating unit 211 in which a heating unit is in contact with the fluid in the storage tank 100;
a second storage tank heating unit 212 disposed within the storage tank 100 and including a transfer unit 212-1 in which a heating element circulates at a constant speed; A water purification device for medical devices including.
In claim 1,
A purification unit 600 that performs a purification process on the fluid and supplies it to the storage tank 100; A water purification device for medical devices including.