SU1707459A1 - Cube ice generator - Google Patents

Description

to cooler 7, provided with capillary-light coating 16.

In the center of the bottom of the ice mold, there is a hole in which the pipes 17 are made of non-heat conductive material, connecting the cavity of the ice mold with the coating 16. The plane of the bottom 6 is inclined towards the tube 17. On the ice mold body adjacent to the hole in the bottom 6, a sealing gasket 18 is fixed .

The ice agent works as follows.

. The power supply unit 13 of the ice maker is connected to the power supply network. Ice molds can be located on the Discharge ejection (figure 1, dotted line). To convert the ice generator to the Cooling mode, the hand rotates the ice mold around the stand, winding it into the cutout 3. After turning 180 ° by pressing the housing 1, the ice mold is fixed in contact with the bottom 6 of the latch 12. This turns on the power of the thermoelectric cooler 7, the fan 9 and the relay time unit 14 controls. Then proizodolt green water in ice form from the tank 10.

The ice form is cooled to a temperature of -5 ...- 10 ° C, in this case the water crystallizes in the cells 2. After the set time, which corresponds to the end of ice formation, the time relay of the control unit 14 operates. which switches the polarity of the thermoelectric cooler 7. At the same time, voltage is applied to the coil of the latch 12, which releases the ice mold body.

The bottom of the ice mold, made of heat conducting material, heats up faster than the ice mold shell. made of material with low thermal conductivity. A thin bottom layer of ice in the cells is 2 sub-tube, while the body 1 of the ice-floe along with the ice 19 rises above the bottom of the ice and is transferred to the extended position above the ice-cap 15, and ice cubes fall out.

The water obtained by tapping the bottom layer of ice flows down the inclined bottom 6 into the tube 17 and soaks the capillary-porous coating 16 of the ribbed heat exchanger 8. A water with a temperature close to 0 ° C cools the heat exchanger radiator, which reduces

working time to obtain cubic ice. During the subsequent ice-producing cycle, when the tube 17 closes the opening 17 with a gasket 18 and the heating of the ribbed zod-heat exchanger evaporates from the capillary-porous coating, they realize the effect of additional evaporative cooling of the heat exchanger 8 and at the same time remove the residual water from the ice form,

Claims (1)

Thus, equipping the heat exchanger with a capillary-porous coating and making the bottom of the ice form oblique allow to intensify the heat exchange on the hot side of the thermoelectric cooler, which improves the performance of the ice generator. Claims of Ice Cubic Ice Generator, containing,: / - ice mold of a material with low thermal conductivity, including a case with through / tM cells, having a downwardly expanding shape, provided with a casing with a thermally insulated lid. a pivot axis in the form of a vertical stand, on which the console of the ice mold is mounted in a cantilever with the difficulty of turning up and down 160 ° until it interacts with a fixed heat-conducting bottom. thermoelectric cooler of ice form with a finned heat exchanger and a fan, a container with nozzles for pouring water into each cell of an ice mold mounted on a thermocleasable the cover of the casing, the fixation of the positions of the ice mold, the control unit associated with the clamp, and the ice acceptor, which is characterized by the fact that, in order to improve the performance, for estimates of heat exchange intensification on the hot thermoelectric cooler, the heat exchanger between the rvbrmmi at the side adjacent to cooler, provided with a capillary-porous coating in the center the bottom of the ice mold is made a hole, a tube of non-heat conducting material is placed in the hole, connecting the coated ice mold cavity, the bottom plane is inclined towards the hole, and not the ice mold housing adjacent to the –hole in the bottom; Reinforced sealing gasket. / J