CN105627606A - Ice machine condensation system - Google Patents

Abstract

The invention relates to an ice machine condensation system, and more particularly, an ice machine condensation system repeatedly using a refrigerant supplied to an ice roller without cooling water. The ice machine condensation system comprises a refrigerant supply pipe supplying the refrigerant, the ice roller reclaiming the refrigerant by using the refrigerant supply pipe and including a refrigerant reclaiming pipe, a first refrigerant entry connected with the refrigerant reclaiming pipe, a second refrigerant outlet exhausting refrigerant injected into the first refrigerant inlet, a first thermal exchanger composed of the second refrigerant inlet and the second refrigerant outlet connected with the refrigerant supply pipe exhausting the refrigerant injected into the second refrigerant inlet, an inlet receiving refrigerant from the first refrigerant outlet of the first thermal exchanger, a compressor exhausting compressed refrigerant and including an outlet, and a refrigerant injecting inlet receiving the refrigerant from the outlet of the compressor, and a second thermal exchanger exhausting the refrigerant injected from the refrigerant injecting inlet to the second refrigerant inlet of the first thermal exchanger and including a refrigerant outlet.

Description

Ice machine condenser system

Technical field

The present invention is about ice machine condenser system, says it is to cool down water in more detail, utilizes to the ice machine condenser system of the cold enzyme circulation Reusability of ice making roller supply.

Background technology

Generally having an ice machine point two ways utilizing water to be frozen into ice cube, a kind of is the mode of trash ice, and also having a kind of is mode like snowflake ice.

Also with good grounds ice making form divides two ways, and a kind of is mode water being poured in bucket directly formed, and also has a kind of mode being to make snowflake with roll shape ice machine.

Roll shape ice machine box house has the barrel-shaped roller that can rotate, a part for this roller can be soaked in water, the inside of roller rotates roller while being poured into the cooling of cold enzyme by refrigerating plant and the water that the surface of roller adheres to is cooled to ice, contact with the surface of roller with sharp skates, the ice of ice making roller case surface is whittled into snowflake.

Above-mentioned roll shape ice machine is formed a cold enzyme blood circulation by compressor, condenser and expansion valve at cold enzyme comb, and the nozzle that these cold enzyme blood circulation are transported cold enzyme in ice making roller sprays.

This roll shape ice machine motion Korean registered patent the 0821558th (title of invention: roll shape ice maker) includes the ice making roller possessing fine groove, the internal cold enzyme supply pipe possessing cold enzyme blending space is run through in the side of above-mentioned ice making roller, supply the injection that combines together of pipe with above-mentioned cold enzyme to support to take to and supply cold enzyme in cold enzyme blending space, the cold enzyme suction tube connected with one end is supported with above-mentioned injection, the nozzle that pipe connects is supplied with cold enzyme, for the two ends cold enzyme suction inlet close with the inlet of above-mentioned cold enzyme suction tube and cold enzyme supply pipe, and between above-mentioned ice making roller and cold enzyme supply pipe device in order to prevent in ice making roller cold enzyme to reveal, ice making roller can be supported on the feature of the support portion of cold enzyme supply tubular shaft.

Simultaneously, Korean patent No. the 0878589th (title of invention: roll shape ice maker) motion is the ice making roller that processes of sanding surface and the side of the above-mentioned ice making roller cold enzyme supply pipe that possesses cold enzyme feed path, with the homogeneous portion of cold enzyme that the inside of the end connection that above-mentioned cold enzyme supplies pipe possesses spray orifice, cold enzyme is sprayed in the cooling space of the above-mentioned homogeneous connecting connection parts of cold enzyme, possesses jet nozzle connector internal closing simultaneously to the homogeneous portion of cold enzyme of same length, it is connected in the cold enzyme feed path of above-mentioned cold enzyme supply pipe, one end is designed to be exposed, the through roller of the other end of cold enzyme suction tube composition connects the cold enzyme suction tube of cooling space upper end, and comprise anti-cold draining enzyme in ice making roller between above-mentioned cold enzyme ice making roller and cold enzyme supply pipe, pipe support portion is supplied with the cold enzyme of bearings ice making roller.

But, the cooling water cooling down cold enzyme that traditional ice machine uses, utilize and be once vented directly to outside afterwards. Therefore to be continuously, during operating ice machine, the worry that ice machine supplies water, also can waste substantial amounts of water.

Summary of the invention

The invention solves the problems that a difficult problem is to cool down the condenser system that cold enzyme is cooled down by water.

Another difficult problem that the invention solves the problems that is that the ice machine standing charges making snowflake minimize.

Another difficult problem that the invention solves the problems that is to produce the snowflake of homogeneous ice matter state.

The condenser system of ice machine of the present invention includes the cold enzyme supply pipe supplying cold enzyme, the ice making roller including cold enzyme recovery tube that the cold enzyme being supplied pipe by above-mentioned cold enzyme is reclaimed, the first cold enzyme entrance with the connection of above-mentioned cold enzyme recovery tube, the second cold enzyme outlet that the cold enzyme that above-mentioned first cold enzyme entrance injects is discharged, first heat exchanger of the second cold enzyme outlet composition that the above-mentioned cold enzyme supply pipe that the cold enzyme that the second cold enzyme entrance and above-mentioned second cold enzyme entrance inject is discharged connects, discharge the compressor including outlet from the entrance of the first of the first above-mentioned heat exchanger the cold enzyme outlet cold enzyme of reception and above-mentioned entrance and receive the cold enzyme inlet of cold enzyme from above-mentioned compressor outlet after compression refrigerant, the cold enzyme that above-mentioned cold enzyme inlet injects is discharged to the second heat exchanger including cold enzyme outlet that cold enzyme entrance connects with the second of above-mentioned first heat exchanger.

The condenser system of ice machine of the present invention includes the cold enzyme supply pipe supplying cold enzyme, the ice making roller including cold enzyme recovery tube that the cold enzyme being supplied pipe by above-mentioned cold enzyme is reclaimed, the first cold enzyme entrance with the connection of above-mentioned cold enzyme recovery tube, the second cold enzyme outlet that the cold enzyme that above-mentioned first cold enzyme entrance injects is discharged, first heat exchanger of the second cold enzyme outlet composition that the above-mentioned cold enzyme supply pipe that the cold enzyme that the second cold enzyme entrance and above-mentioned second cold enzyme entrance inject is discharged connects, discharge the compressor including outlet from the entrance of the first of the first above-mentioned heat exchanger the cold enzyme outlet cold enzyme of reception and above-mentioned entrance and receive the cold enzyme inlet of cold enzyme from above-mentioned compressor outlet after compression refrigerant, the cold enzyme that above-mentioned cold enzyme inlet injects is discharged to the second heat exchanger including cold enzyme outlet that cold enzyme entrance connects with the second of above-mentioned first heat exchanger. and include one end and be connected to the cold enzyme outlet of above-mentioned second heat exchanger, the other end is connected to the first cold enzyme inlet of above-mentioned first heat exchanger, and the expansion valve of the cold enzyme of above-mentioned injection is discharged in cooling.

The condenser system of ice machine of the present invention is not utilize cooling water, utilizes the cold enzyme cooling reclaimed from ice making roller to be supplied to the cold enzyme of ice making roller. Therefore the condenser system simple structure of invention ice machine, and new hand also can install equipment easily.

Again, the condenser system of ice machine of the present invention does not utilize cooling water to cool down cold enzyme, can effectively reduce the standing charges of ice machine.

Accompanying drawing explanation

Fig. 1 diagram ice machine condenser system according to a kind of embodiment.

Fig. 2 illustrates the ice machine condenser system according to another kind of embodiment.

Fig. 3 is the diagram ice machine condenser system according to another embodiment.

105: ice making roller 110: compressor

115: the first heat exchanger 120: the second heat exchangers

125: fan 130: expansion valve

105-1: cold enzyme supply pipe 105-2: cold enzyme nozzle

105-3: the cold enzyme entrance of cold enzyme recovery tube 115-1: the first

115-2: the first cold enzyme entrance of cold enzyme outlet 115-3: the second

115-4: the second cold enzyme outlet 120-1: cold enzyme entrance

120-2: cold enzyme outlet 140: high pressure plate heat exchanger

Detailed description of the invention

Narrate the additional present invention and can carry out example by referring to additional drawing, can definitely. By example of the invention below, easier gives when dealer understands and explanation.

Fig. 1 diagram ice machine condenser system according to a kind of embodiment. Figure 1 below is utilized to understand the ice machine condenser system according to a kind of embodiment in more detail.

According to Fig. 1, the condenser system of ice machine includes ice making roller, compressor, the first heat exchanger, the second heat exchanger and fan. Beyond additionally above-mentioned component parts, other parts can also be included in above-mentioned ice machine condenser system.

Rotate ice making roller (150), device supplies pipe (105-1) at the cold enzyme within ice making roller, cold enzyme nozzle (105-2), utilizes cold enzyme recovery tube (105-3) to reclaim the cold enzyme being ejected into ice making roller (150) inner surface. That is, ice making roller (105) utilizes the cold enzyme from the injection of cold enzyme nozzle to be cooled down on the surface of ice making roller, and the cold enzyme of cooling ice making surface is reclaimed by cold enzyme recovery tube (105-3). By cold enzyme supply pipe (105-1) although the cold enzyme injected is the liquid form of high pressure, but the cold enzymic change ejected by cold enzyme nozzle is to the gas form of low-pressure low-temperature. Cold enzyme recovery tube (105-3) reclaims the cold enzyme of the gas form of low-temp low-pressure.

The first cold enzyme entrance (115-1) that the cold enzyme that first heat exchanger includes reclaiming from cold enzyme recovery tube (105-3) enters and the first cold enzyme outlet (115-2) discharged by the cold enzyme of the first cold enzyme entrance. It addition, the first heat exchanger (115) includes again the second cold enzyme entrance (115-3) that the cold enzyme that the second heat exchanger (120) discharges enters and the second cold enzyme outlet (115-4) of the cold enzyme discharge that the second cold enzyme entrance (115-3) enters.

The cold enzyme being injected into the first cold enzyme entrance (115-1) presents the gaseous state of low-temp low-pressure, and reverse side is injected into the cold enzyme of the second cold enzyme entrance (115-3) and presents gas or the liquid condition of High Temperature High Pressure. That is, the cold enzyme temperature being injected into the first cold enzyme entrance (115-1) is lower than the cold enzyme temperature being injected into the second cold enzyme entrance (115-3) comparatively speaking. Therefore, the present invention utilizes the cold enzyme being injected into the first cold enzyme entrance (115-1) to cool down the temperature of the cold enzyme being injected into the second cold enzyme entrance (115-3).

Second cold enzyme outlet (115-4) supplies pipe (105-1) with the cold enzyme of ice making roller (105) and is connected, and the cold enzyme therefore discharged from the second cold enzyme outlet (115-4) is supplied to cold enzyme supply pipe (105-1)

First cold enzyme outlet (115-2) is connected with compressor (110), and the cold enzyme that therefore the first cold enzyme outlet (115-2) is discharged is supplied to compressor (110).

It is supplied to the second heat exchanger (120) after the cold enzyme compression that compressor (110) supplies the first of the first heat exchanger (115) the cold enzyme outlet (115-2). That is, compressor (110) is supplied to the second heat exchanger (120) after the cold enzyme turnover of low pressure to high pressure. The gas injected to compressor (110) and liquid cold enzyme weight proportion comparatively speaking more important than gasiform weight ratio greatly. Therefore, compressor (110) comprises the inlet injecting cold enzyme and discharges the outlet of cold enzyme.

The cold enzyme outlet (120-2) that the cold enzyme that second heat exchanger (120) comprises cold enzyme entrance (120-1) and injection is discharged. Cold enzyme entrance (120-1) is connected with compressor (110), and cold enzyme outlet (120-2) enzyme cold with the second of the first heat exchanger entrance (115-3) is connected. Second heat exchanger (120) is supplied to the second cold enzyme entrance (115-3) of the first heat exchanger (115) the cold enzyme being flowed into compressor (110).

The ice machine condenser system of the present invention comprises fan (125), first heat exchanger (115) is arranged on the side of heat exchanger (115), another once mounting the second heat exchanger (120) for benchmark fan (125). The distance of the second comb of the position of a part of the first comb of the connection first cold enzyme entrance (115-1) of the first heat exchanger (115) and the first cold enzyme outlet (115-2) and the connection second cold enzyme entrance (115-3) of the first heat exchanger (115) and the second cold enzyme outlet (115-4) comparatively speaking can be larger than the distance with fan (125).

Fan (125) utilizes external impetus to rotate, and the cold air that the wind that fan rotates produces first row tube-surface is communicated to second row tube-surface. The cold air passing to second row tube-surface cools down the cold enzyme within the second comb. The cold enzyme that the above-mentioned cold enzyme cold air cooling second row pipe flow showing to utilize first row pipe flow dynamic of the present invention is dynamic.

Additionally, the another side of the fan that the second heat exchanger (120) position is benchmark at the first heat exchanger (115), so the cold air that first row tube-surface produces can be communicated to the second heat exchanger (120), also can by the cooled flow cold enzyme in the second heat exchanger (120) inside by the method.

Therefore the cold air of the cold enzyme that present invention utilization is reclaimed from ice making roller (105) cools down the cold enzyme being supplied to ice making roller (105). Then need not cool down water to cool down.

Ice machine of the present invention does not need cooling water device, therefore can be simple than structure before, has advantage easy for installation.

Although Fig. 1 diagram utilize fan coolling first heat exchanger and and the cold enzyme of internal heat exchanger, be not limited to this. That is, the present invention comprises the first heat exchanger and each fan corresponding to the second heat exchanger, utilizes fan to rotate the cold enzyme that can cool down the first heat exchanger and the second internal heat exchanger.

Although Fig. 1 illustrates the cold enzyme that cold enzyme recovery tube reclaims and is supplied to the first cold enzyme entrance of the first heat exchanger, it is not limited to this. That is, the second heat exchanger and the first heat exchanger equally comprise the first cold enzyme entrance and the first cold enzyme outlet, and the cold enzyme discharged from compressor is injected into the second cold enzyme entrance and is injected into the second cold enzyme outlet that the cold enzyme of the second cold enzyme entrance is discharged. First cold enzyme entrance of the first same first heat exchanger of cold enzyme entrance of the second heat exchanger flows into the cold enzyme that cold enzyme recovery tube reclaims. That is, the first cold enzyme inlet portion of Leng Mei recovery tube branch and the first heat exchanger connects, and the first cold enzyme inlet portion of another and the second heat exchanger connects. Therefore being connected by the first cold enzyme entrance of one, Leng Mei recovery tube branch and the first heat exchanger, the first cold enzyme entrance of another and the second heat exchanger connects the cold enzyme temperature reduction that can make to be supplied to cold enzyme supply pipe. No doubt the cold enzyme that the first cold enzyme outlet of the first of the first heat exchanger the cold enzyme outlet and the second heat exchanger flows out is supplied to compressor.

Fig. 2 diagram ice machine condenser system according to a kind of embodiment. Figure 1 below is utilized to understand the ice machine condenser system according to a kind of embodiment in more detail.

According to Fig. 2, the condenser system of ice machine includes ice making roller, compressor, the first heat exchanger, the second heat exchanger and expansion valve. Beyond additionally above-mentioned component parts, other parts can also be included in above-mentioned ice machine condenser system.

Rotate ice making roller (150), device supplies pipe (105-1) at the cold enzyme within ice making roller, cold enzyme nozzle (105-2), utilizes cold enzyme recovery tube (105-3) to reclaim the cold enzyme being ejected into ice making roller (150) inner surface. That is, ice making roller (105) utilizes the cold enzyme from the injection of cold enzyme nozzle to be cooled down on the surface of ice making roller, and the cold enzyme of cooling ice making surface is reclaimed by cold enzyme recovery tube (105-3). By cold enzyme supply pipe (105-1) although the cold enzyme injected is the liquid form of high pressure, but the cold enzymic change ejected by cold enzyme nozzle is to the gas form of low-pressure low-temperature. Cold enzyme recovery tube (105-3) reclaims the cold enzyme of the gas form of low-temp low-pressure.

The first cold enzyme entrance (115-1) that the cold enzyme that first heat exchanger includes reclaiming from cold enzyme recovery tube (105-3) enters and the first cold enzyme outlet (115-2) discharged by the cold enzyme of the first cold enzyme entrance. It addition, the first heat exchanger (115) includes again the second cold enzyme entrance (115-3) that the cold enzyme that the second heat exchanger (120) discharges enters and the second cold enzyme outlet (115-4) of the cold enzyme discharge that the second cold enzyme entrance (115-3) enters.

The cold enzyme being injected into the first cold enzyme entrance (115-1) presents the gaseous state of low-temp low-pressure, and reverse side is injected into the cold enzyme of the second cold enzyme entrance (115-3) and presents gas or the liquid condition of High Temperature High Pressure. That is, the cold enzyme temperature being injected into the first cold enzyme entrance (115-1) is lower than the cold enzyme temperature being injected into the second cold enzyme entrance (115-3) comparatively speaking. Therefore, the present invention utilizes the cold enzyme being injected into the first cold enzyme entrance (115-1) to cool down the temperature of the cold enzyme being injected into the second cold enzyme entrance (115-3).

Connect the comb branch of the second cold enzyme outlet (115-4), one comb of branch supplies pipe (105-1) with the cold enzyme of ice making roller (105) and is connected, and another comb of branch is connected with expansion valve (130). Therefore the cold enzyme part that the second cold enzyme outlet (115-4) is flowed out is supplied to cold enzyme supply pipe (105-1), and another part is supplied to expansion valve (130).

Expansion valve (130) flows into cold enzyme from the first heat exchanger. Expansion valve (130) becomes low pressure cold enzyme the cold enzyme turnover of high pressure flowed into. Namely, expansion valve (130) is transformed into low pressure after the cold enzyme of high pressure is expanded, temperature step-down when cold enzyme temperature when being flowed out by this expansion valve (130) is compared toward expansion valve (130) inflow. and the cold enzyme flowed out from expansion valve (130) is supplied to the first cold enzyme entrance (125-1) of the first heat exchanger (115).

Therefore the present invention utilizes the cold enzyme of a part that the second cold enzyme outlet (115-4) of the first heat exchanger (115) is flowed out by the cold enzyme after utilizing cooling after expansion valve (130) cooling, internal for the second comb of the first heat exchanger cold enzyme to be cooled down again.

First cold enzyme outlet (115-2) of the first heat exchanger (115) is connected with compressor (110), and the cold enzyme that the first cold enzyme outlet (115-2) is flowed out is supplied to compressor (110).

It is supplied to the second heat exchanger (120) after the cold enzyme compression that compressor (110) supplies the first of the first heat exchanger (115) the cold enzyme outlet (115-2). That is, compressor (110) is supplied to the second heat exchanger (120) after the cold enzyme turnover of low pressure to high pressure. The gas injected to compressor (110) and liquid cold enzyme weight proportion comparatively speaking more important than gasiform weight ratio greatly. Therefore, compressor (110) comprises the inlet injecting cold enzyme and discharges the outlet of cold enzyme.

The cold enzyme outlet (120-2) that the cold enzyme that second heat exchanger (120) comprises cold enzyme entrance (120-1) and injection is discharged. Cold enzyme entrance (120-1) is connected with compressor (110), and cold enzyme outlet (120-2) enzyme cold with the second of the first heat exchanger entrance (115-3) is connected. Second heat exchanger (120) is supplied to the second cold enzyme entrance (115-3) of the first heat exchanger (115) the cold enzyme being flowed into compressor (110).

The ice machine condenser system of the present invention comprises fan (125), first heat exchanger (115) is arranged on the side of heat exchanger (115), another once mounting the second heat exchanger (120) for benchmark fan (125). The distance of the second comb of the position of a part of the first comb of the connection first cold enzyme entrance (115-1) of the first heat exchanger (115) and the first cold enzyme outlet (115-2) and the connection second cold enzyme entrance (115-3) of the first heat exchanger (115) and the second cold enzyme outlet (115-4) comparatively speaking can be larger than the distance with fan (125).

Fan (125) utilizes external impetus to rotate, and the cold air that the wind that fan rotates produces first row tube-surface is communicated to second row tube-surface. The cold air passing to second row tube-surface cools down the cold enzyme within the second comb. The cold enzyme that the above-mentioned cold enzyme cold air cooling second row pipe flow showing to utilize first row pipe flow dynamic of the present invention is dynamic.

Additionally, the another side of the fan that the second heat exchanger (120) position is benchmark at the first heat exchanger (115), so the cold air that first row tube-surface produces can be communicated to the second heat exchanger (120), also can by the cooled flow cold enzyme in the second heat exchanger (120) inside by the method.

Therefore the cold air of the cold enzyme that present invention utilization is reclaimed from ice making roller (105) cools down the cold enzyme being supplied to ice making roller (105). Then need not cool down water to cool down.

Ice machine of the present invention does not need cooling water device, therefore can be simple than structure before, has advantage easy for installation.

Fig. 2 diagram ice machine condenser system according to a kind of embodiment. Figure 1 below is utilized to understand the ice machine condenser system according to a kind of embodiment in more detail.

According to Fig. 2, the condenser system of ice machine includes ice making roller, compressor, the first heat exchanger, the second heat exchanger and expansion valve. Beyond additionally above-mentioned component parts, other parts can also be included in above-mentioned ice machine condenser system.

Rotate ice making roller (150), device supplies pipe (105-1) at the cold enzyme within ice making roller, cold enzyme nozzle (105-2), utilizes cold enzyme recovery tube (105-3) to reclaim the cold enzyme being ejected into ice making roller (150) inner surface. That is, ice making roller (105) utilizes the cold enzyme from the injection of cold enzyme nozzle to be cooled down on the surface of ice making roller, and the cold enzyme of cooling ice making surface is reclaimed by cold enzyme recovery tube (105-3). By cold enzyme supply pipe (105-1) although the cold enzyme injected is the liquid form of high pressure, but the cold enzymic change ejected by cold enzyme nozzle is to the gas form of low-pressure low-temperature. Cold enzyme recovery tube (105-3) reclaims the cold enzyme of the gas form of low-temp low-pressure.

The first cold enzyme entrance (140-1) that the cold enzyme that high pressure plate heat exchanger (140) includes reclaiming from cold enzyme recovery tube (105-3) enters and the first cold enzyme outlet (140-2) discharged by the cold enzyme of the first cold enzyme entrance. It addition, high pressure plate heat exchanger (140) includes again the second cold enzyme entrance (140-3) that the cold enzyme that compressor (110) discharges enters and the second cold enzyme outlet (140-4) of the cold enzyme discharge that the second cold enzyme entrance (140-3) enters.

The cold enzyme being injected into the first cold enzyme entrance (140-1) presents the gaseous state of low-temp low-pressure, and reverse side is injected into the cold enzyme of the second cold enzyme entrance (140-3) and presents gas or the liquid condition of High Temperature High Pressure. That is, the cold enzyme temperature being injected into the first cold enzyme entrance (140-1) is lower than the cold enzyme temperature being injected into the second cold enzyme entrance (140-3) comparatively speaking. Therefore, the present invention utilizes the cold enzyme being injected into the first cold enzyme entrance (140-1) to cool down the temperature of the cold enzyme being injected into the second cold enzyme entrance (140-3).

Connect the comb branch of the second cold enzyme outlet (140-4), one comb of branch supplies pipe (105-1) with the cold enzyme of ice making roller (105) and is connected, and another comb of branch is connected with expansion valve (130). Therefore the cold enzyme part that the second cold enzyme outlet (140-4) is flowed out is supplied to cold enzyme supply pipe (105-1), and another part is supplied to expansion valve (130).

Expansion valve (130) flows into cold enzyme from high pressure template heat-heat exchanger (140). Expansion valve (130) becomes low pressure cold enzyme the cold enzyme turnover of high pressure flowed into. Namely, expansion valve (130) is transformed into low pressure after the cold enzyme of high pressure is expanded, temperature step-down when cold enzyme temperature when being flowed out by this expansion valve (130) is compared toward expansion valve (130) inflow. and the cold enzyme flowed out from expansion valve (130) is supplied to the first cold enzyme entrance (140-1) of high pressure plate heat exchanger (140).

Therefore the present invention utilizes the cold enzyme of a part that the second cold enzyme outlet (140-4) of high pressure plate heat exchanger (140) is flowed out by the cold enzyme after utilizing cooling after expansion valve (130) cooling, internal for the second comb of high pressure plate heat exchanger (140) cold enzyme to be cooled down again.

First cold enzyme outlet (140-2) of high pressure plate heat exchanger (140) is connected with compressor (110), and the cold enzyme that the first cold enzyme outlet (140-2) is flowed out is supplied to compressor (110).

The second cold enzyme entrance (140-3) of high pressure plate heat exchanger (120) it is supplied to after the cold enzyme compression that compressor (110) supplies the first of high pressure plate heat exchanger (140) the cold enzyme outlet (140-2).

Although present invention drawing illustrates embodiment, but is the example indicated, if the professional person in industry is understood that what other diversified or similar embodiments were also possible to.

Claims (7)

1. receive the cold enzyme supply pipe of cold enzyme, above-mentioned the ice making roller including cold enzyme recovery tube reclaimed by the cold enzyme of above-mentioned cold enzyme supply pipe,

The first cold enzyme entrance with the connection of above-mentioned cold enzyme recovery tube, the second cold enzyme outlet that the cold enzyme that above-mentioned first cold enzyme entrance injects is discharged, first heat exchanger of the second cold enzyme outlet composition that the above-mentioned cold enzyme supply pipe that the cold enzyme that the second cold enzyme entrance and above-mentioned second cold enzyme entrance inject is discharged connects

From the first of the first above-mentioned heat exchanger the cold enzyme outlet receive the entrance of cold enzyme and above-mentioned entrance to discharge after compression refrigerant the compressor including outlet and

Receive the cold enzyme inlet of cold enzyme from above-mentioned compressor outlet, the cold enzyme that above-mentioned cold enzyme inlet injects is discharged to the condenser system that the second heat exchanger is feature including cold enzyme outlet that cold enzyme entrance connects with the second of above-mentioned first heat exchanger.

2. receive the cold enzyme supply pipe of cold enzyme, above-mentioned the ice making roller including cold enzyme recovery tube reclaimed by the cold enzyme of above-mentioned cold enzyme supply pipe,

The first cold enzyme entrance with the connection of above-mentioned cold enzyme recovery tube, the second cold enzyme outlet that the cold enzyme that above-mentioned first cold enzyme entrance injects is discharged, first heat exchanger of the second cold enzyme outlet composition that the above-mentioned cold enzyme supply pipe that the cold enzyme that the second cold enzyme entrance and above-mentioned second cold enzyme entrance inject is discharged connects

From the first of the first above-mentioned heat exchanger the cold enzyme outlet receive the entrance of cold enzyme and above-mentioned entrance to discharge after compression refrigerant the compressor including outlet and

The first cold enzyme entrance with the connection of above-mentioned cold enzyme recovery tube, the cold enzyme that above-mentioned first cold enzyme entrance flows into is discharged, the second cold enzyme outlet that the entrance of above-mentioned compressor is connected, the second cold enzyme entrance of cold enzyme and the cold enzyme discharge of above-mentioned second cold enzyme entrance inflow, the ice machine condenser system that the second heat exchanger is feature that the second cold enzyme outlet being connected with above-mentioned cold enzyme supply pipe is included is received from above-mentioned compressor outlet.

3. receive the cold enzyme supply pipe of cold enzyme, above-mentioned the ice making roller including cold enzyme recovery tube reclaimed by the cold enzyme of above-mentioned cold enzyme supply pipe,

The first cold enzyme entrance with the connection of above-mentioned cold enzyme recovery tube, the second cold enzyme outlet that the cold enzyme that above-mentioned first cold enzyme entrance injects is discharged, first heat exchanger of the second cold enzyme outlet composition that the above-mentioned cold enzyme supply pipe that the cold enzyme that the second cold enzyme entrance and above-mentioned second cold enzyme entrance inject is discharged connects

From the first of the first above-mentioned heat exchanger the cold enzyme outlet receive the entrance of cold enzyme and above-mentioned entrance to the compressor including outlet discharged after compression refrigerant and

Side is connected with the cold enzyme outlet of above-mentioned second heat exchanger, and opposite side then enzyme entrance cold with the first of above-mentioned first heat exchanger is connected, and that discharges after the cold enzyme cooling of above-mentioned inflow includes the ice machine condenser system that expansion valve is feature.

4. any one in claim 1-3 includes relying on the fan that external impetus rotates,

Above-mentioned first heat exchanger is that benchmark side is provided with above-mentioned fan, and opposite side installs the condenser system of the ice machine that above-mentioned second heat exchanger is feature.

5., according to claim 4, the position of the comb that the second cold enzyme entrance of the first comb some first heat exchanger that compares minimum that the first cold enzyme entrance of above-mentioned first heat exchanger and the first cold enzyme outlet are connected and the second cold enzyme outlet connect to be close to the ice machine condenser system of feature from fan.

6., according to claim 1-3 any one, minimum want 2 fans by what external impetus rotated,

One fan is blown toward above-mentioned first heat exchanger, the ice machine condenser system that another fan is feature toward above-mentioned second heat exchanger air-supply.

7. receive the cold enzyme supply pipe of cold enzyme, above-mentioned the ice making roller including cold enzyme recovery tube reclaimed by the cold enzyme of above-mentioned cold enzyme supply pipe,

The first cold enzyme entrance with the connection of above-mentioned cold enzyme recovery tube, the second cold enzyme outlet that the cold enzyme that above-mentioned first cold enzyme entrance flows into is discharged, the high pressure plate heat exchanger of the second cold enzyme outlet composition that the above-mentioned cold enzyme supply pipe that the cold enzyme that the second cold enzyme entrance and above-mentioned second cold enzyme entrance inject is discharged connects

From the first cold enzyme outlet of high pressure version type heat exchanger receive the entrance of cold enzyme and above-mentioned entrance to discharge after compression refrigerant the compressor including outlet and

Side is connected with the second cold enzyme outlet of high pressure version type heat exchanger, and opposite side is then connected with the first cold enzyme entrance of high pressure version type heat exchanger, and that discharges after the cold enzyme cooling of above-mentioned inflow includes the ice machine condenser system that expansion valve is feature.