JPH046379A - Refrigerator - Google Patents

Abstract

PURPOSE:To obtain a refrigerator capable of supplying the output of contracted cold air not only to the side of an ice making chamber but also to the side of a quick freezing chamber with a simple constitution by providing a switching means for switching the output flow passage of the contracted cold air to either the side of the ice making chamber or the side of the quick freezing chamber. CONSTITUTION:A switching means is constituted of an upper contracted cold air partitioning plate 19, equipped with nozzle holes 18 for injecting contracted cold air into a quick freezing chamber 9, and a jet stream switching shutter 20 provided in a contracted cold air flow passage. A knob 22 for operating the shutter 20 is pulled out fully to the outside of the contracted cold air flow passage 7 and is operated so as to move the knob 22 within a predetermined width in fore-and-back direction whereby the flow passage of the output of the jet stream cold air of the contracted cold air flow passage 7 can be switched to the side of an ice making chamber 12 or the quick freezing chamber 9. The speed of the output of the jet stream cold air is high and the jet stream collides against food stuff 11 or water in an ice making pan 13 energetically whereby heat transfer efficiency is very high and heat exchanging effect is promoted so as to be capable of not only ice making but also the high-speed cooling of materials received in the quick freezing chamber 9.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a refrigerator that takes into account the efficient operation of a condensed air passage used in an ice-making compartment within a freezer compartment.

[Prior Art] FIG. 5 is a longitudinal sectional view of the vicinity of the freezing compartment of a conventional refrigerator disclosed in, for example, Japanese Patent Application No. 63-242832.

In the figure, (1) is the refrigerator body, (2) is the freezer compartment partitioned within the refrigerator body (1), (3) is a cooler that cools the circulating cold air, and (4) is a cold air circulation fan.

(5) is a fan grill, and (6) is a duct that guides cold air.

(7) is a condensation air passage that narrows down the cold air, (8) is a quick freezing fan that accelerates the constriction cold air, (9) is a quick freezing chamber located above the contraction air passage (7), and (io) is a rapid freezing fan that accelerates the constriction air passage. Freezer room (9)
(11) is the food placed on the tray (10), (12) is the ice-making compartment at the bottom of the condenser air passage (7), (13) is inside the ice-making compartment (12) The ice tray (14) is an upper condenser partition plate (15) that covers the upper part of the convergent air passage (7) and demarcates the boundary with the deep freezing chamber (9).
) covers the lower part of the condensation air passage (7), and the condensation cold air is passed through the ice tray (
13) is a partition plate with a lower nozzle equipped with a nozzle that blows into the air, (16) is a cold air intake port, (17) is a cold air passage,
(18) is a nozzle hole.

Next, the operation will be explained.

The cold air cooled by the cooler (3) is passed through the cold air circulation fan (4).
) and sent out into the freezer compartment (2) and into the duct (6). The cold air that passed through the duct (6) further flows to the quick freezing chamber (9) on one side to cool the food (11),
The other side is diverted to the contracted air passage (7), and is connected to the quick freezing fan (
8), and the cold air is blown through the constriction air path (
7), the cold air is narrowed down and speeded up. The speed of this cold air is further increased by passing through the nozzle hole (8) provided in the lower nozzle-equipped partition plate (15), and the direction of the cold air is controlled by the nozzle hole (18) within the contracted air passage (7). What used to be horizontal has been changed to vertical.

The ice tray (13) forms a jet from directly above the ice tray (13).
Collision with the water inside. Since this jet has a high wind speed, the heat transfer coefficient between the water surface and the cold air becomes very large due to the impinging jet effect, so heat exchange is promoted and the water in the ice tray (13) quickly freezes.

[Invention or problem to be solved] A conventional refrigerator is configured as shown above.

The supply of condensed cold air without increased speed is limited to the ice-making compartment, and food stored in the quick-freezing compartment cannot be cooled at high speed.

This invention was made to solve the above-mentioned problems, and its purpose is to provide a refrigerator with a simple configuration that can supply condensed cold air not only to the ice-making compartment but also to the quick-freezing compartment. do.

[Means for Solving the Problems] A refrigerator according to the present invention is provided with means for switching the output air path of condensed cold air to the ice-making compartment side or the quick-freezing compartment side.

[Function] The switching means in the present invention switches the output of the condensed cold air to the ice making compartment side or the quick freezing compartment side, and also supplies the constricted cold air to the food stored in the quick freezing compartment.

[Embodiments of the invention] An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a vertical cross-sectional view of the vicinity of a freezing chamber showing an embodiment of the present invention. In FIG. Avoid. (19) is a constriction flow partition plate with an upper nozzle equipped with a nozzle hole (18) for spouting constriction cold air into the quick freezing chamber (9), and (20) is a jet flow provided in the convection air path. This switching shutter is a plate-shaped member that can be moved inscribed in the partition plate of the contracted air passage (7). By moving a predetermined width in the front-rear direction, the slit (21) opens and closes the nozzle hole (18). (22) is a knob for operating the shutter (20), and (23) is a stopper that fixes the movement width of the shutter (20).

Note that the contracting flow partition plate (I9) and the shutter (20) constitute a switching means.

Next, the operation will be explained below with reference to FIG.

The process up to the exit side of the contracted air passage (7) is exactly the same as that described in the conventional technology, but Fig. 2(a) shows the shutter (20
) to the outside of the contraction air duct (7).
The upper slit (21al) on the shutter (20) has the upper nozzle hole (18a) opened, and the lower slit (21bl) has the lower nozzle hole (18a) opened on the shutter (20).
b) is closed, and the jet of contractile cold air is sent to the deep freezing chamber (9).
) side is supplied. On the contrary, as shown in FIG. 2(b), when the knob (22) is pushed into the inner cup of the contracted air passage (7), the lower nozzle hole 08b) shown in the figure opens, and the upper nozzle hole opens. (18a) will be closed, and the ice making compartment (18a) will be closed.
2) Supply the jet output of the contraction air passage (7) to the side. By moving the knob (22) in the front-back direction by a predetermined width in this manner, the output air path of the jet cold air of the contracted flow air path (7) can be switched to the ice making compartment (12) side or the quick freezing compartment (9) side. The output of this jet of cold air has a high wind speed and force (
Since the jet collides with the food (11) and the water in the ice tray (I3), the heat transfer coefficient is extremely high (the heat exchange action is promoted, and the water in the quick freezing chamber (9) is Stored items can be cooled quickly.

FIG. 3 shows another embodiment.

In this example, by rotating the knob (22), the shutter (20) opens the nozzle hole 8) on the deep freezing compartment side in Figure 3(a) and on the ice making compartment side in Figure 3(b). ing. One or more rows of slits (2I) are provided on the shutter (20), and when the knob (22) is rotated by a predetermined width, the upper nozzle hole (18a) or the lower nozzle hole (18
b) Alternately drill holes.

FIG. 4 shows an embodiment corresponding to the left-right direction when the knob (22) in FIG. 2 is operated in the front-back direction.

In FIG. 4(a), there are two rows of upper or lower nozzle holes (only slits are shown in the figure), and by moving the knob (22) by a predetermined width (indicated by a), the upper or lower nozzle holes can be opened. (18) are drilled alternately. Figure 4 (b
) is a diagram in which the knob has been moved in the left-right direction - to the right of the cup, and the shutter (20) has an upper nozzle hole (18a) opened. Similarly, if the shutter (20) is moved to the left by the amount "a" shown in the figure, the upper nozzle hole (18a) will be closed and the lower nozzle hole (18bl) will be opened. Example According to the invention, the shutter (2
0) by simply moving the knob (22) by a predetermined width.
The output cold air air path of the contracted flow air path (7) can be switched to the ice making room side or the quick freezing room side.

The knob (22) may be operated manually or may be operated electrically, for example, without being limited thereto.

In addition, in the above embodiment, a condensation air passage (
7) has been described as a configuration in which the quick freezing chamber (9) is placed above the contracted air passage (7), but this is just an example.
Although it is ideal to blow condensed cold air onto the ice tray (13) from above, it is not necessarily limited to this. Similarly, the quick freezing chamber (9) can be placed at the top of the constricted air passage (7). There is no necessity to place it.

Nozzle holes (18
), the shutter (20) can open and close the nozzle hole, and the air path of contracted cold air can be switched between the ice-making compartment (12) and the quick-freezing compartment (9).

Further, the dimensions and shapes of the nozzle hole (18) and the slid (21) are not particularly limited, but the shapes thereof are the same.

If the dimensions are almost the same, there is no problem with separate installation.

[Effects of the Invention] As described above, according to the present invention, ice can be made with a simple configuration because a means is provided for switching the output air path of the condensed cold air supplied by the condensed air path to the ice making compartment side or the quick freezing compartment side. This has the effect of providing a refrigerator that can rapidly cool not only the food stored in the refrigerator compartment but also the food stored in the quick-freezing compartment.

[Brief explanation of drawings]

FIG. 1 is a sectional view showing the vicinity of the freezer compartment of a refrigerator in an embodiment of the present invention, FIGS. aisle, (
18) is a nozzle hole, (19) is a partition plate with an upper nozzle, (20) is a shutter, and (21) is a slid. (22) is a knob, and (23) is a stopper. In addition, in FIG. 9, the same reference numerals indicate the same or corresponding parts.

Claims (1)

[Scope of Claims] A refrigerator main body, an ice-making compartment and a quick-freezing compartment partitioned within the main body, a cooler for cooling the air inside the refrigerator main body, and a cooler for cooling the air cooled by the cooler for cooling the air inside the refrigerator main body. A quick-freezing fan that circulates to the ice-making compartment and the quick-freezing compartment is installed between the ice-making compartment and the quick-freezing compartment, and the cold air sent from the quick-freezing fan is condensed and sped up to a high speed. The invention is characterized by comprising: a condensation air path that converts the air into cold air and sends it to the ice-making compartment and the quick-freezing compartment; and a switching means provided in the condensation air passage for selectively supplying the high-speed cold air to the ice-making compartment and the quick-freezing compartment. Refrigerator.