RU2256128C1 - Thermoelectric ice-making machine - Google Patents

Abstract

FIELD: manufacture of thermoelectric ice-making machines.

SUBSTANCE: proposed thermoelectric ice-making machine has housing with ice mold mounted on it which is provided with thermoelectric modules and straight-flow heat exchangers on vertical walls and hinged cover under it, reservoir above ice mold and polarity selector switch of thermoelectric modules. Thermoelectric ice-making machine is provided with water filter mounted in housing above reservoir equipped with thermoelectric modules and straight-flow heat exchangers on its vertical hat-conducting walls, drain branch pipe with cock fitted on the outside of housing under reservoir and reversible motor mechanically linked with pusher located between vertical walls of ice mold and hinged cover; water filter is hydraulically connected with reservoir, straight-flow heat exchangers of reservoir and ice mold; reservoir is hydraulically connected with drain branch pipe and ice mold.

EFFECT: increased productivity of ice-making machine.

6 cl, 5 dwg

Description

The invention relates to refrigeration, in particular to small-sized thermoelectric ice machines for producing pieces of block ice, used, for example, in the preparation of chilled drinks. It can be applied at the enterprises of trade, a public catering, in offices and house conditions.

Known thermoelectric ice machine (AS USSR No. 1763818, F 25 C 1/12, 1992, Bulletin 35). This device is used to obtain thin-layer ice on the elements and cannot be used to prepare blocks of block ice. Known thermoelectric ice machine (AS USSR 1723415, F 25 C 1/12, 1992, Bulletin 12), intended for the preparation of lump tubular ice (classification according to the textbook for universities "Refrigeration" Moscow, 1991, pg. 352-356) in a moving car. Cooling of the heated sides of thermoelectric modules in it occurs due to the oncoming air flow. Thermal conductivity of air is 2.1 kcal / m · h · deg, and water 47.4 kcal / m · h · deg. Therefore, the performance of thermoelectric ice-makers with air cooling is much lower than with instantaneous water cooling. The thermoelectric ice maker according to Russian patent No. 2225969, F 25 C 1/12 of 2004 is also intended for the preparation of lump tubular ice and it also uses air cooling of thermoelectric modules. The drop filling of water into the ice form used in this invention can be effective only in the ice form with a tubular section, since the drop in it spreads uniformly throughout its diameter and quickly cools.

An analogue of the invention is the invention as. USSR No. 1753213, F 25 C 1/12 (1992, Bulletin 29) “Thermoelectric ice machine”. It contains mounted on a horizontal axis, with the possibility of rotation, a cooling unit comprising an ice form with freezing elements. Under the ice mold and on it are placed thermoelectric batteries with flowing heat exchangers. This thermoelectric ice maker provides a container from where water is poured into the cells of the ice form. But it does not provide for preliminary purification of water passing through flowing heat exchangers and poured from the tank into ice molds. Therefore, it is possible to contaminate the channels of flowing heat exchangers, which reduces the reliability of their operation, and the ice from untreated water in the ice form is opaque. In the tank where the water is poured into the ice form, its preliminary cooling is not provided, which does not make it possible to reduce the preparation time of blocks of block ice in the ice form, and therefore, increase the performance of the thermoelectric ice maker. This thermoelectric ice maker does not provide for the possibility of forming a stock of purified “ice” water with the possibility of spilling it in small portions. It does not automate the process of unloading pieces of ice from ice form cells; they fall from them under their own weight. In this case, a piece of ice may hang in the ice-forming cell due to surface tension forces generated in the water layer during thawing of the surface layer of an ice piece, which reduces the performance and reliability of the thermoelectric ice-maker.

For the prototype, the patent of Russia No. 2122693, F 25 C 1/12 of 1998 “Thermoelectric ice generator” was selected. An ice mold with a flat bottom and vertical side walls, on which thermoelectric modules with flowing heat exchangers are located, is installed in the body of the ice maker. The cover of the ice mold has rods that are frozen into a piece of block ice and with which you can manually unload a piece of ice from the ice mold. Then, also manually, using the ejector button, a piece of ice is removed from the rods. As can be seen from the description, there are manual operations that increase the time to produce a piece of ice, which reduces the performance of the thermoelectric ice maker. The process of unloading a piece of ice from an ice mold for rods frozen into it is unreliable, since it is possible, with a certain effort and insufficient freezing of the rods in ice, pulling them out of a piece of ice, which in this case can remain in place, in an ice form. In this thermoelectric ice machine, as well as in the analogue, preliminary treatment of water passing through the channels of flowing heat exchangers and poured into an ice mold is not provided, which reduces the reliability of the thermoelectric ice generator and reduces the transparency of the obtained piece of ice. And since there is no possibility of pre-cooling the water poured into the ice mold, there is no possibility of reducing the preparation time of a block of block ice, and therefore of the possibility of increasing the performance of the thermoelectric ice generator. It does not provide for the possibility of forming a supply of “ice” purified water and the possibility of pouring it in small portions, for example, for preparing chilled cocktails, which does not make it possible to expand the functionality of a thermoelectric ice maker.

The problem solved by the invention is the improvement of a thermoelectric ice machine. The technical result consists in increasing the productivity of the thermoelectric ice machine by reducing the time for preparing a block of block ice in the ice form and unloading it from there, in increasing the reliability of its operation by reducing the pollution of the channels of flow heat exchangers, increasing the purity and transparency of the piece of block ice obtained from water due to its preliminary cleaning in an ice machine, in expanding the functionality of a thermoelectric ice machine, namely providing The formation of a stock of “iced” purified water in it with the possibility of bottling it in small portions, for example, for preparing chilled cocktails.

The specified technical result is achieved by the fact that the thermoelectric ice maker is equipped with a water filter mounted in the housing above the tank and hydraulically connected to it. Therefore, the water poured into the tank, first passes through the filter, being purified at the same time. Then the purified water from the tank is used for feeding into the ice mold, since the tank is hydraulically connected through the electrohydro valve to the ice mold. The tank is made with thermoelectric modules and flow heat exchangers on its vertical, heat-conducting walls. Thermoelectric modules through heat-conducting walls cool the water in the tank to the temperature of “ice” water (<+ 10 ° С). The vertical arrangement of the side walls of the tank, on which the thermoelectric modules are located, makes it possible to pass water through the channels of flowing heat exchangers for cooling the heated sides of the modules by gravity under their own weight. A portion of the water in the ice form obtained from the tank is not only previously cleaned, but also cooled. This can significantly reduce the time for preparing a piece of ice in the ice form. Since the water filter is hydraulically connected to the flow heat exchangers, purified water passes through their channels, which significantly reduces the deposition of salts, for example, on the walls of the channels, which significantly increases the reliability of the flow heat exchangers. It should be noted that in this invention all the hydraulic elements of the filter, tank, flow heat exchangers, ice molds, drain pipes are arranged sequentially in parallel from top to bottom, which makes it possible to pass water through them by gravity without using a water pump, which greatly simplifies the design of the thermoelectric ice machine . The presence of a reversible engine makes it possible not only to force a block of block ice out of the ice mold, while opening the hinged lid, but also to return the pusher to its original position, while again closing the ice mold with a hinged lid and, thereby, automatically prepare the ice mold for filling it with a new portion of water . These actions increase the reliability of unloading a block of block ice from the ice form and reduce the time of auxiliary operations aimed at preparing and filling the ice form. The analysis shows, due to which in this invention increases the performance and reliability of the thermoelectric ice machine as a whole. The presence of a drain pipe with a tap mounted outside the housing under the tank and hydraulically connected to it makes it possible to use the stock of purified “ice” water from the tank, pouring it in small portions using a tap, for example, for preparing chilled cocktails, which extends the functionality of the thermoelectric ice machine . The implementation of hydraulic connections in the ice machine through electrohydro valves, as well as the presence of temperature and water level sensors in the tank, electrically connected to thermoelectric modules and electrohydro valves, will fully automate the process of preparing the stock of purified “ice” water in the tank and a transparent, environmentally friendly block of ice in ice form , which also helps to increase the performance of the thermoelectric ice machine. Filling holes in the ice mold pusher simplify the process of pouring into it a portion of purified “ice” water from the tank. The execution outside the body, under the ice mold, of an additional drain pipe hydraulically connected with the flow heat exchangers of the container and the ice mold, allows the use of purified water from them for domestic purposes. The platform under the ice mold allows you to install a glass there and load a piece of block ice directly into it, which increases the usability of the thermoelectric ice maker.

Figure 1 shows a thermoelectric ice maker connected to a water supply, a general view; figure 2 is a General view of a thermoelectric ice machine in the context; figure 3 is a section aa; figure 4 is a section bB; figure 5 is a section bb.

The thermoelectric ice machine (Figs. 1 and 2) contains a housing 1, an ice mold 2 installed in it (Fig. 2) with thermoelectric modules 3 and flow heat exchangers 4 on its vertical walls and with a hinged lid 5 under the ice mold 2. A container 6 is installed above the ice mold. The housing 1 is equipped with a power polarity switch 7 (FIGS. 1 and 2), which simultaneously gives a command to unload a piece of ice 35 from the ice mold 2 (FIG. 2). In the housing 1, a water filter 8 is installed above the tank (any of those commercially available, for example, a membrane one, such as “Trickle” 1C, Vladimir, JSC Polymersynthesis), through which water from the water supply system 33 through a hose 32 enters the tank previously pre-treated with a filter. Capacity 6 is made with thermoelectric modules 9 and flow-through heat exchangers 10 on its vertical walls, which are heat-conducting. The ice maker is equipped with a drain pipe 11 with a crane 12 installed outside the housing 1 under a capacity of 6, as well as a reversible motor 13 of the type of direct current motor RD, which can be installed anywhere inside the housing 1 both inside and outside. It is mechanically connected through a system of levers 14, screws and nuts (not shown in FIG.) To a pusher 15 (FIGS. 2 and 5) made between the vertical walls of the ice mold 2 and to a hinged cover 5. The water filter 8 is hydraulically, for example, through a hose 16, is connected with capacity 6 (Fig. 2), through hoses 17 with flow-through heat exchangers 9 of capacity 6 and flow-through heat exchangers of ice mold 2. Capacity 6 is hydraulically connected through a hose 18 to a drain pipe 11. A water filter 6 is hydraulically connected to the capacity, flow-through heat exchangers of the tank and ice forms through an electrog droklapany 19, 20 and 21. Volume 6 is hydraulically connected with a drain pipe 11 and the ice mold Electrohydraulic 2 through 22 and 23.

The tank 6 is made with water level sensors 24 and its temperature 25, electrically connected (in Fig. Shown) with thermoelectric modules of the tank and all the electrohydro valves of the ice maker. In the pusher 15 (FIGS. 2 and 5), filling holes 26 are made through which purified, cooled water from the tank 6 is poured into the ice mold 2 through the electrohydrovalve 23 (not shown in FIG.). Outside of the housing 1, under the ice mold 2 (FIGS. 2 and 1), an additional drain pipe 27 is made, hydraulically connected through the hoses 28 and 29 to the flow heat exchangers 4 of the container and the ice mold 2. In the housing 1, under the ice mold 2, a platform 30 for installing the cup 31 is made. A hose 32 connects the filter 8 to the water supply 33 on which the tap 34 is located. Figure 2 shows a piece of environmentally friendly, transparent block ice 35 discharged from the ice mold 2. Figure 1 and 2 show that the thermoelectric ice maker is mounted on a stand 36 ( which can be bought ) For easy draining of water from the nozzle 27.

Thermoelectric ice generator operates as follows.

The switch 7 is pressed to the “OHL” position (FIGS. 1 and 2), while thermoelectric modules 9 are connected to the mains via a voltage converter from 220 V to 12 V (not shown in FIG.) And electrohydro valves 19, 20, 21 (FIG. 2). The tap 34 of the water supply 33 is open and tap water through the hose 32 enters the water filter 8 of the ice maker. Tap water in the filter is cleaned of harmful impurities and through hoses 16 and 17 through open electrohydro valves 19, 20, 21 it enters respectively the heat transfer tank 6 and the flow heat exchangers 10 and 4 of the tank 6 and ice mold 2. In the flow heat exchangers 10 and 4, the purified water is moved by gravity , under its own weight, through channels 37 and 38 (Figs. 3, 4, 5). These channels, due to the post-treatment of water in the filter 8 (Fig. 2), become clogged much less and for a longer time, the possibility of reliable cooling of the thermoelectric modules 9 and 3 remains. The purified water fills the tank 6 to the level set by the float sensor 24. It gives the command to turn on the thermoelectric modules 9 located on the vertical, heat transfer walls of the vessel 6. Due to the Pelt effect, one side of the thermoelectric modules 9, which is in contact with the walls of the vessel 6, is cooled, thereby cooling cutting the heat-conducting walls and the stock of purified water 39 in the tank 6. The other side of the thermoelectric modules 9 in contact with the flow heat exchangers 10 is heated (Fig.3), the heat from which is removed by running, purified water through the channels 37 of the heat exchangers 10. Thermoelectric modules 9 and the electrohydro valve 20 is turned on until the temperature of the water supply 39 in the tank 6 reaches a predetermined value, for example, + 5 ° C (“ice” water). The temperature level is set using the temperature sensor 25 (figure 2). Upon reaching the set temperature, the sensor 25 gives the command to open the electrohydro valves 22 and 23. The purified “ice” water then enters the drain pipe 11 and stops in front of the closed valve 12. By opening it (manually), you can pour purified “ice” water in small portions. When the valve 23 is open, a portion of the purified “ice” water from the tank 6 can flow through the hose 40 through the filler holes 26 of the pusher 15 into the ice mold 2. The volume of the water portion can be regulated, for example, due to the opening and closing times of the electrohydro valve 23. This electrohydro valve gives a command to the inclusion of thermoelectric modules 3 located on the vertical walls of the ice form 2. The process of cooling water in the ice form and heat removal from thermoelectric modules 3 occur similarly to the same process on vertical, heat-conducting x the walls of the tank 6 described above. A portion of water in ice form 2 is cooled until it turns into a piece of ice 35. Since this piece of ice is formed from purified "ice" water, the formation of a piece of ice is significantly reduced in time and it turns out to be transparent. The command to unload a piece of ice 35 from the ice mold 2 may be given by a time relay (not shown in FIG.). In this case, the reversible engine 13 is turned on, and the pusher 15 starts to move downward, opening the hinged cover 5 due to the articulated levers 14 (Fig. 2). The indicated time relay can also give a command for automatically switching the polarity of power of thermoelectric modules 3. In this case, the cold side of thermoelectric modules 3 becomes heated for a short time, and the heated cold and surface layer of ice block 35 in ice form 2 thaws, which helps to force the ice out ice molds, for example, in a glass 31, previously installed on the platform 30 of the housing 1 of the thermoelectric ice machine. Switching the polarity of thermoelectric modules 3 and turning on the reversing motor 13 for unloading a block of block ice 35 can also be done manually, if necessary, by pressing switch 7 (Figs. 1 and 2) to the “Win” position. A piece of ice 35 in ice form 2 can be stored for a long time time with automatic voltage reduction on thermoelectric modules from 12 V to 6 V to save energy. Thus, such a thermoelectric ice maker makes it possible to prepare, store and dispense a block of block ice in an environmentally friendly, transparent manner with greater productivity and reliability, and also makes it possible to form a stock of purified “ice” water with spillage in small portions.

Claims (6)

1. Thermoelectric ice machine, comprising a housing, an ice mold installed therein with thermoelectric modules and flow heat exchangers on the vertical walls and with a hinged lid under it, a container above the ice mold and a polarity switch for supplying thermoelectric modules, characterized in that the thermoelectric ice machine is equipped with a water filter installed in case above the tank, made with thermoelectric modules and flow heat exchangers on its vertical heat-conducting walls, drain pat a compartment with a tap mounted outside the housing under the tank and a reversible motor mechanically connected to the pusher made between the vertical walls of the ice mold and with a hinged lid, the water filter being hydraulically connected to the tank, flow heat exchangers of the tank and ice mold, and the tank was hydraulically connected to the drain branch pipe and ice mold. 2. The thermoelectric ice maker according to claim 1, characterized in that the water filter is hydraulically connected to the tank, flow heat exchangers of the tank and ice molds through electrohydro valves, and the tank is hydraulically connected to a drain pipe with a tap and ice mold through electrohydro valves. 3. Thermoelectric ice maker according to claim 1 or 2, characterized in that the tank is made with water level and temperature sensors, electrically connected to thermoelectric modules, electrohydro valves. 4. The thermoelectric ice machine according to claim 1, characterized in that in the ice mold pusher filling holes are made. 5. The thermoelectric ice maker according to claim 1, characterized in that on the outside of the casing, under the ice mold, an additional drain pipe is made hydraulically connected to the flow heat exchangers of the container and the ice mold. 6. The thermoelectric ice maker according to claim 1, characterized in that in the housing under the ice mold is made a platform for installing a glass.

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