KR200448110Y1 - Ice maker able to maintain water flow quantity uniformly - Google Patents

Abstract

The present invention discloses an ice maker capable of stably supplying a constant flow rate regardless of the pressure change of the water supply source, enabling stable operation of the ice maker and preventing the deterioration of ice quality.

The ice maker of the present invention has a plurality of ice-forming pockets and is provided with a pocket plate 40 on which an evaporator pipe 41 is piped, and sprays water to the pocket plate 40 through a nozzle 50. Water supply control for generating ice cubes and a water supply pipe 70 for supplying ice-making water supply above the pocket plate 40, and intercepting the flow of water supplied from an external water supply source to the water supply pipe 70. As an ice maker provided with the valve 100, a passage forming member 200 and a pressure response plate 300 are installed inside the discharge port 120 of the feedwater control valve 100, and the passage forming member 200 is provided. A body 210 inserted into and fixed to the discharge port 120 to block a passage; A shaft portion 220 protruding from the body 210 in an opposite direction to the outlet and having a main passage 221 opened in the axial direction; A plurality of gap maintaining protrusions 211 protruding from the body 210 to a height lower than the shaft portion 220 in the protruding direction of the shaft portion 220 from the circumference of the shaft portion 220. and; And a plurality of control passages 231 which are formed to be opened in the body 210 between the gap holding protrusions 211, wherein the pressure throttle plate 300 is elastically pressed by the pressure of water supply. It is made of a material material is fitted to the shaft portion 220 to be in close contact with the gap maintaining projection jaw (211); Maintaining a gap between the outer circumference and the inner circumference of the discharge port 120 through which water can pass; On the surface facing the passage forming member 200, a plurality of grooves 320 are formed in which the plurality of gap maintaining protrusions 211 are partially inserted in the axial direction, and are formed by the adjacent grooves 320. A plurality of pressing plate portion 330 maintains a gap between the body 210 end surface of the passage forming member 200 and the water supply can pass, the pressing of the pressure response plate 300 as the pressure of the water supply increases The plate portion 330 is gradually pressed, and the water supply passage gap between the pressed plate portion 330 and the passage forming member 200 is gradually narrowed to further obstruct the control passage 231 to pass through the control passage 231. The water supply is configured to gradually decrease.

Ice maker, water supply, flow rate, control, ice, valve, pressure response plate, pressing plate

Description

ICE MAKER ABLE TO MAINTAIN WATER FLOW QUANTITY UNIFORMLY}

The present invention relates to a water supply control valve for an ice maker, and more particularly, to an ice maker that maintains a constant water supply flow rate so that a constant flow rate can be stably supplied regardless of a pressure change of a water supply source.

As shown in FIG. 1, an ice maker for manufacturing crushed ice includes an ice reservoir 20 below the inside of the case 10, and an ice maker 31 and a water storage compartment on the ice reservoir 20. (32) is divided up and down by the sliding grill plate 33, and on one side of the ice making chamber 31 is provided with an ice making tank (30) provided with a door 34, the ice making chamber 31 for forming a plurality of ice A pocket plate 40 having pockets is installed, and also includes a pump 60 for pumping water stored in the water supply storage chamber 32 and supplying and spraying the nozzle 50 toward the pocket plate 40. In addition, a water supply pipe 70 for supplying ice making water is installed above the pocket plate 40 of the ice making room 310, and one side of the case 10 is supplied to the water supply pipe 70 from an external water supply source. Water supply control valve 100 to control the flow of water to be installed In addition, the pocket plate 40 has a configuration in which the evaporator pipe 41 of the refrigeration system is piped.

In such an ice maker, when water is injected into the pocket plate 40 cooled by the refrigerant passing through the evaporator pipe 41 through the pump 60 and the nozzle 50, the sprayed water freezes and accumulates in the cooled pocket. do. When the ice fills the inside of the pocket, refrigerant hot gas is passed through the evaporator pipe 41 to heat the pocket plate 40, and at the same time, the water supply control valve 100 is opened to open the pocket plate 40 through the water supply pipe 70. When the water is sprayed on the upper part, the pocket plate 40 is heated by the refrigerant hot gas and water supply, and the surface of the pocket and the ice are instantly thawed in a minute manner so that the crushed ice generated in the pocket is dropped by the natural falling method. In addition, the ice cubes are broken down along the sliding grill plate 33 to pass through the door 34 to be accumulated in the ice storage tank 20. On the other hand, the water supplied to the ice making chamber 31 through the water supply pipe 79 passes through the hole of the sliding grill plate 33 and is stored in the water supply storage chamber 32. If too much water accumulates in the water storage compartment 32, it is drained out through the drain pipe 80.

In such an ice maker, the conventional water supply control valve 100 only serves to open the water supply pipe by a control signal at the time of defrosting, but does not control the flow rate of the water supply due to excessive or insufficient supply of water. Many problems arise.

This can be done by installing ice makers in ordinary homes or factories, installations with low water pressure, high water pressure, or using small or large feed pumps. Since the supply pressure of the water supply is severely changed depending on the capacity of the source, the amount of water passing through the feedwater control valve 100 becomes severe, causing many problems. For example, assuming that the required water pressure of the water supply source is 3 kgf / cm 2 and the water supply control valve is manufactured accordingly, the actual water pressure is very widely formed to 1 to 6 kgf / cm 2 depending on the installation environment. If the ice maker is installed under such a situation, a dropping phenomenon occurs when the water supply pressure is low, and when the water supply pressure is high, ice formation time is delayed, resulting in a decrease in productivity and a problem such as water overflowing into the ice storage tank 20. .

For example, if the water supply pressure of the external water supply source is too low, the amount of water discharged from the water supply pipe 70 becomes too small, so that the ice generated in the pocket plate does not thaw due to partial ice removal and remains as it is without falling off. In this state, when the ice making process is performed again, new ice layers are formed on the remaining ice, and the ice is overflowed to the outside of the pocket, and the overflowed ice is transferred to another adjacent adjacent pocket plate. Sticking by ice, that is, the phenomenon of redness occurs. When such a drop occurs, the shape of the ice cube is distorted and deteriorated, and the pocket plate is stuck, so that the ice making process cannot be performed smoothly.

In addition, when the water supply pressure of the external water supply source is high, the amount of water discharged from the water supply pipe 70 to the pocket plate 40 at the time of ice removal becomes too large, so that the temperature of the pocket plate 40 becomes high and the pocket is subjected to the next ice making process. It takes a long time to cool the plate 40 back to a deicable temperature, thereby reducing productivity. In addition, if the water supply pressure of the water supply source is too high, very much water enters in a short time during defrosting, the natural drainage capacity of the drain pipe (80) can not afford it, the water overflows from the water storage compartment 32 flows into the ice storage tank (20) It will enter and destroy the stored pieces of ice.

In contrast, conventionally, a cock valve was attached to the water supply pipe so that the user could adjust it according to the situation. However, general users have insufficient understanding of the ice maker, and according to the pressure of the water supply source and the pressure of the water supply source, In many cases, it may not be possible to adjust the opening degree of the cock valve, so the practical installation effect was not achieved.

The present invention was developed to improve the problems of the conventional ice makers as described above, so that a constant flow rate can be stably supplied at all times regardless of the pressure change of the water supply source to enable stable operation of the ice maker and the quality of ice cubes. An object of the present invention is to provide an ice maker that can prevent a decrease.

A pocket plate having a plurality of ice-forming pockets and piped with an evaporator pipe is installed, and spraying water to the pocket plate through a nozzle to generate ice cubes, and to supply ice water to the pocket plate. A water ice making machine is provided with a water supply pipe and a water supply control valve for intermitting the flow of water supplied from an external water supply source to the water supply pipe, wherein a passage forming member and a pressure response plate are installed inside the discharge port of the water supply control valve. The forming member includes: a body inserted into the discharge hole and installed to block a passage; A shaft portion protruding from the body in a direction opposite to the outlet and having a main passage opening in the axial direction; A plurality of spacing projection projections having a shape extending radially from the circumference of the shaft portion and protruding from the body at a height lower than the shaft portion in a protruding direction of the shaft portion; And a plurality of control passages that are opened to the body between the spacing projection protrusions, wherein the pressure response plate is made of an elastic flexible material pressed by the pressure of water supply and fitted to the shaft portion so as to fit the gap. In close contact with the holding projection jaw; Maintaining a clearance between the outer circumference and the inner circumference of the discharge port through which water can pass; The groove facing the passage forming member is formed with a plurality of groove portions into which the plurality of gap holding protrusions are partially inserted in the axial direction, and a plurality of pressing plate portions formed by the adjacent groove portions are end portions of the body of the passage forming member. Consists of the surface and the gap through which the water supply can pass, the pressure plate of the pressure response plate is gradually pressed as the pressure of the water supply increases, so that the water supply passage gap between the pressing plate and the passage forming member gradually increases. It becomes narrower so as to block the control passage gradually so that the amount of water passing through the control passage gradually decreases, so that the water supply at almost constant flow rate is always supplied regardless of the pressure change of the water supply source.

In the ice maker of the present invention described above, it is preferable that the pressure response plate is made of an elastic flexible rubber.

In the ice maker according to the present invention, the passage forming member is preferably made of a plastic injection molding.

In the icemaker according to the present invention, the size of the total flow passage cross-sectional area of the plurality of control passages is larger than the flow passage cross-sectional area of the main passage so that the control can be more effective.

As the ice maker according to the present invention increases the pressure of the external water supply source, the pressing plate portion of the pressure response plate is gradually pressed, so that the water supply passage gap with the passage forming member is gradually narrowed, so that the water flow rate passing through the main passage increases. Instead, the flow rate of the feedwater through the control passage is reduced, so that even if the feedwater pressure increases, there is little or no variation in the flowrate to the ice maker.

Therefore, according to the ice maker according to the present invention, by preventing the phenomenon of water overflowing into the ice storage tank by the accumulation phenomenon or excessive water supply, it is possible to stable operation of the ice maker and contribute to the improvement of ice quality and productivity.

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

1 schematically shows an ice maker according to the present invention. The repeated description for the above-described parts will be omitted.

The ice maker of the present invention is provided with a water supply control valve 100 in the water supply pipe 70 so that the amount of water supplied from the external water supply source to the water supply pipe 70 of the ice maker is always kept constant. The water supply control valve 100 serves to interrupt (open / close) the water supply pipe 70 as in the prior art, and is configured to maintain a constant water supply flow rate exiting the outlet even if the pressure of the water supply increases by the present invention. have. The water supply control valve 100 is installed at one side of the case 10 of the ice maker, and the inlet port 110 protrudes from the case 10 to the outside and a screw is formed at the periphery so that the external water supply pipe can be connected. .

2 is an enlarged cross-sectional view of the water supply control valve 100 enlarged than it is. As shown in FIG. 2, the water supply control valve 100 includes an inlet port 110 for connecting an external water supply pipe and a discharge port 120 for discharging water to the water supply pipe 70 (see FIG. 1). And a solenoid valve 130 for opening and closing a passage between the inlet 110 and the outlet 120 by a control signal.

In particular, the flow rate control unit 200a for automatically adjusting the opening degree of the discharge port 120 in accordance with the water supply pressure in the discharge port 120 of the water supply control valve 100 to adjust the flow rate of the water supplied to the ice maker. Is installed.

Figure 3a, 3b and 4 is an enlarged view of the structure of the flow control unit 200a, Figure 3a is an exploded perspective view, Figure 3b is an assembled perspective view, Figure 4 is a cross-sectional view Is shown.

As shown in Figures 3a, 3b and 4, the flow rate control unit 200a of the present invention, the passage forming member 200 and the pressure response plate (installed inside the discharge port 120 of the water supply control valve 100) Including a 300, the pressure response plate 300 is made to adjust the opening degree of the passage forming member 200 in accordance with the water supply pressure of the external water supply source.

The passage forming member 200 is installed in a state in which the body 210 is inserted into and fixed to the discharge hole 120 to block the water supply discharge passage of the discharge hole 120. In addition, the shaft portion 220 protrudes in the axial direction in the direction opposite to the outlet from the body 210, and the shaft portion 220 has a main passage 221 through which water is passed. On the surface of the body 210 around the shaft portion 220, a plurality of gap maintenance beads 211 are formed in the protrusion direction of the shaft portion 220. The gap maintaining protrusion jaw 211 is formed to extend radially from the circumference of the shaft portion 220, and has a lower height than the shaft portion 220. In addition, a control passage 231 is formed in each of the body 210 between the spaced projection protrusions 211.

The passage forming member 200 is preferably made of a plastic injection molding from the viewpoint of ease of manufacture, and more preferably made of POM (polyoxymethylane, polyoxymethylene) in the plastic.

The pressure response plate 300 is made of an elastic and flexible material pressed by the pressure of the water supply. For example, it is made of an elastic flexible rubber such as EPDM (Ethylene Propylene Diene Monomer Rubber). The pressure response plate 300 is fitted to the shaft portion 220 through a coupling hole 310 formed at the center thereof and is in close contact with the spaced projection protrusion 211. In addition, the pressure response plate 300 is made of a smaller diameter than the installation hole 121 so as to maintain a gap between the outer circumference and the inner circumference of the discharge port 120, the installation hole 121 and the installation hole ( 121) it is installed to have an inner end surface 122 and a fox space.

In addition, a plurality of grooves 320 in which the plurality of gap maintaining protrusions 211 are partially inserted in the axial direction are formed on one surface of the pressure response plate 300 facing the passage forming member 200. A plurality of pressing plate portions 330 are formed between the adjacent groove portions 320 by the formation of the plurality of groove portions 320, and the pressing plate portions 330 are protruding jaws 211 for maintaining gaps in the groove portions 320. ) Is deep enough to be closer to the end surface of the body 210 of the passage-forming member 200 by the amount to be inserted. For example, when the pressure responding plate 300 is made of a flat plate and is simply flat on the space keeping protrusion 211, deformation (depression) of the portion contacting the space keeping protrusion 211 is difficult, As a result, the gap in this portion remains almost the same no matter how the water supply pressure increases (because it cannot actively or proportionally cope with the increase in water supply pressure) so that too much water flows through the control passage 231. On the other hand, the pressure response plate 300 according to the present invention is composed of a combination of the groove portion 320 and the pressing plate 330, because the pressing plate 330 has a form already entered a predetermined depth, than when the flat plate When the water supply pressure increases, the pressing plate 330 is pressed more and more proportionally. As the water supply pressure increases, the pressure is increased so that the water supply entering the control passage 231 is blocked further proportionally. In response to this, it is effectively reduced.

Here, the size of the total flow passage cross-sectional area of the plurality of control passages 231 is larger than the flow passage cross-sectional area of the main passage 221. On the contrary, since the main passage 221 maintains the same state at all times regardless of the fluctuation of the water supply pressure and is not a control object, the passage flow rate increases proportionally as the water supply pressure increases. In the plurality of control passages 231, the passages must be narrowed in preparation for an increase in flow rate and an increase in the passage flow rate due to an increase in water supply pressure, and by further reducing the passage flow rate increase of the main passage 221, Control can be easily performed only by securing a large flow passage cross-sectional area of the control passages 231 to be controlled to widen the control range (adjustment range). For example, as in the embodiment shown in the drawing, if the cross-sectional area of one control passage 231 is set equal to the cross-sectional area of the main passage 221 and the number of control passages 231 is set to three, the control passage Since the total cross-sectional area of 231 becomes three times the cross-sectional area of the main passage 221, it can be said that it is appropriate.

In the ice maker of the present invention made as described above, as shown in FIG. 1, the water is pumped through the pump 60 and the nozzle 50 to the pocket plate 40 cooled by the refrigerant passing through the evaporator pipe 41. When spraying, the sprayed water freezes on the cooled pocket and is stacked. When the ice is filled in the pocket of the pocket plate 40, the hot gas is passed through the evaporator pipe 41 to remove the ice to heat the pocket plate 40 and at the same time the solenoid valve of the water supply control valve 100 130, see FIG. 2) to spray water onto the pocket plate 40 through the water supply pipe 70.

At this time, the water supply control valve 100 is provided with a flow rate control unit 200a, so that even if the pressure of the external water supply source fluctuates, a substantially constant flow rate is supplied to the water supply pipe 70.

If the minimum water supply pressure of the external water supply source required for ice making is 1 kg / cm 2, and the preferred flow rate supplied to the ice maker is 3 l / min, the flow rate passing through the flow regulating unit 200a is 1 kg / cm 2. In this case, the diameters of the main passage 221 and the control passage 231 are set in advance so as to be 3 l / min, and manufactured accordingly. In this case, when the water supply pressure increases to 1 kg / cm 2 or more, the pressure response plate 300 acts, so that the discharge flow rate is hardly changed even when the water supply pressure increases. In fact, in the case of the conventional water supply control valve, when the water supply pressure of the external water supply source is formed between 1 to 6 kg / cm 2, the discharge flow rate increases proportionally to 1 to 10 l / min. According to the control valve 100, when the water supply pressure is formed between 1 ~ 6kg / ㎠ the discharge flow rate was maintained almost constant at 2.9 ~ 3.6L / min.

The operation of the present invention will be described in more detail with reference to FIGS. 4 and 5. 4 is an enlarged cross-sectional view showing an installation state of the flow rate control unit 200a of the water supply control valve 100 according to the present invention as described above, and FIG. 5 is viewed from the direction 'A' of FIG. High water pressure is a view showing the operating state of the flow control unit (200a).

First, in FIG. 4, when the external water supply pressure is close to the minimum pressure, the pressure response plate 300 of the flow control unit 200a hardly changes or changes only slightly as initially set so that the pressure response plate 300 and the discharge port ( The gap between the gap 120 and the gap between the pressure response plate 300 and the body 210 of the passage forming member 200 is maintained. Accordingly, the water supply passing through the solenoid valve 130 (see FIG. 2) and exiting the discharge port 120 exits the main passage 221 and the control passage 231 normally.

If the external water supply pressure is higher than the minimum pressure, the water supply per unit time passing through the main passage 221 increases by the pressure increase, but the water supply passing through the control passage 231 due to the blocking action of the pressure response plate 300. Since the flow rate is reduced by the increase in flow rate in the main passage 221, there is no change in the total flow rate passing through the two passages 221, 231.

Specifically, due to the increase in the water supply pressure, the pressure responding plate 300 is pressed in a state as shown by a dashed-dotted line in FIG. 4 and in a state as shown in FIG. 5 (in FIG. 4 and FIG. It is shown that the pressure response plate 300 is pressed a lot because the water pressure is close to the maximum pressure). When the water supply pressure is increased, the flow rate to the discharge port 120 is faster, thereby increasing the flow rate exiting the main passage 221. However, when the water supply pressure increases, the pressing plate portion 330 of the pressure response plate 300 in the portion between the adjacent gap maintaining projection jaw 211 by pressing the pressure response plate 300 is the passage forming member 200. By closer to or partially in contact with the surface of the body 210, the passage between the pressure responding plate 300 and the body 210 is narrowed to reduce the amount of water supplied into the control passage 231. By this action, even if the external water supply pressure increases in the actual ice maker, the water flow rate entering the ice making chamber 31 through the water supply pipe 70 is always maintained almost constant.

1 is a view schematically showing an ice maker according to the present invention.

2 is an enlarged cross-sectional view of a water supply control valve according to the present invention.

3a and 3b is an exploded perspective view and an assembled perspective view showing an enlarged structure of the flow rate control unit of the water supply control valve according to the present invention.

Figure 4 is an enlarged cross-sectional view showing the installation state of the flow rate control unit of the water supply control valve according to the present invention.

Figure 5 is a view from the 'A' direction of Figure 4 showing the operating state of the flow control unit according to the present invention when the water supply pressure is high.

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

10: case 20: ice promotion

30: ice-making tank 31: ice-making room

32: water reservoir 33: sliding grill plate

34: door 40: pocket plate

41: evaporator pipe 50: nozzle

60: pump 70: water supply line

80: drain pipe 100: water supply control valve

110: inlet 120: outlet

121: mounting hole 122: inner end surface

130: solenoid valve 200: passage forming member

210: body 211: protruding jaw for maintaining gap

220: shaft portion 221: main passage

231: control passage 300: pressure response plate

310: coupling hole 320: groove

330: pressing plate

Claims (4)

A pocket plate 40 having a plurality of ice-forming pockets and having an evaporator pipe 41 piped thereon is installed, and sprays water to the pocket plate 40 through a nozzle 50 to generate ice cubes. A water supply pipe 70 for supplying ice-making water is installed above the pocket plate 40, and a water supply control valve 100 for controlling the flow of water supplied from an external water supply source to the water supply pipe 70 is provided. Ice maker, A passage forming member 200 and a pressure response plate 300 are installed inside the discharge port 120 of the water supply control valve 100, The passage forming member 200 includes: a body 210 inserted into and fixed to the discharge port 120 to block the passage; A shaft portion 220 protruding from the body 210 in an opposite direction to the outlet and having a main passage 221 opened in the axial direction; A plurality of gap maintaining protrusions 211 protruding from the body 210 to a height lower than the shaft portion 220 in the protruding direction of the shaft portion 220 from the circumference of the shaft portion 220. and; And a plurality of control passages 231 which are formed to be opened in the body 210 between the gap maintaining protrusions 211. The pressure response plate 300 is made of an elastic flexible material pressed by the pressure of water supply and fitted to the shaft portion 220 so as to be in close contact with the spacing projection 211. Maintaining a gap between the outer circumference and the inner circumference of the discharge port 120 through which water can pass; On the surface facing the passage forming member 200, a plurality of grooves 320 are formed in which the plurality of gap maintaining protrusions 211 are partially inserted in the axial direction, and are formed by the adjacent grooves 320. A plurality of pressing plate portion 330 maintains a gap through which the water supply and the end surface of the body 210 of the passage forming member 200 can pass, As the pressure of the water supply increases, the pressing plate portion 330 of the pressure response plate 300 is gradually pressed, so that the water supply passage gap between the pressing plate portion 330 and the passage forming member 200 is gradually narrowed so as to control the control plate. An ice maker for maintaining a constant water supply flow rate, characterized in that the water supply passing through the control passage 231 is gradually reduced by further blocking the passage 231. The method of claim 1, The pressure response plate (300) is an ice maker for maintaining a constant water flow rate, characterized in that the elastic flexible rubber. The method of claim 1, The passage forming member (200) is an ice maker for maintaining a constant water flow rate, characterized in that made of a plastic injection. The method of claim 1, The size of the total flow passage cross-sectional area of the plurality of control passages (231) is larger than the flow passage cross-sectional area of the main passage (221), ice machine for maintaining a constant water supply flow rate.

Images