CN217654133U - Slice ice machine evaporator - Google Patents

Abstract

The utility model relates to a piece ice maker evaporimeter, its piece ice maker include the load and set up in the evaporimeter in the load outside, and the evaporimeter is including surrounding the evaporating chamber in the load outside, and the pipe that advances that supplies the refrigerant to let in to and the exit tube that supplies the refrigerant gas to lead to, be provided with the separation blade in the evaporating chamber, and the separation blade sets up on the outer wall of evaporating chamber, advances the pipe and sets up in the top of separation blade, is provided with the clearance between the inner wall of separation blade and evaporating chamber, for the refrigerant falls down from the clearance. The utility model discloses a separation blade makes the load outside form refrigerant liquid face, and the refrigerant falls perpendicularly from the clearance, and the refrigerant gasifies rapidly, improves refrigeration efficiency, reduces the thermal resistance, and it is extravagant to reduce the material, and the refrigerant gasification makes conduction efficiency improve greatly, makes the load can cool down rapidly.

Description

Slice ice machine evaporator

Technical Field

The utility model relates to a piece ice maker evaporimeter.

Background

The flake ice machine is one of ice machines, and is generally an industrial ice machine. The produced ice is in a sheet shape, the sheet ice can be made of fresh water or salt water, the sheet ice is dry loose white ice with the thickness of 10-15 mm, the shape of the product surface is irregular, the diameter is about 12-45 mm, and the sheet ice has no sharp edges and corners and can not stab frozen objects. The flake ice has excellent refrigerating effect and the characteristics of large refrigerating capacity and rapidness, so that the flake ice is mainly applied to various large refrigerating facilities, quick freezing of foods, cooling of concrete and the like.

The evaporator is the core component of flake ice machine, the existing evaporator adopts copper pipe or metal plate pipe structure, it is winded on the external surface of load stainless steel, the refrigerant can be passed through the copper pipe or metal plate pipe to make evaporation and heat absorption and refrigeration, but said structure is complex, its processing cost is high, heat conduction is poor and efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model provides a piece ice maker evaporimeter.

The utility model provides a technical scheme that above-mentioned technical problem adopted does: the ice flake machine comprises a load and an evaporator arranged outside the load, wherein the evaporator comprises an evaporation chamber surrounding the load, an inlet pipe for introducing a refrigerant and an outlet pipe for leading out refrigerant gas, a separation blade is arranged in the evaporation chamber, the separation blade is arranged on the outer wall of the evaporation chamber, the inlet pipe is arranged above the separation blade, and a gap is arranged between the separation blade and the inner wall of the evaporation chamber so that the refrigerant falls down from the gap.

Further, the baffle plate is close to the top of the evaporation chamber.

Further, the baffle plate is arranged at 1/9-1/7 of the evaporation chamber.

Preferably, the baffle is disposed at 1/8 of the evaporation chamber.

Furthermore, the separation blade is provided with the breach, and the exit tube sets up in the top of breach department.

Further, the inlet pipe extends into the evaporation chamber.

Further, the baffle is planar.

Further, the baffle is spiral.

Further, the exit tube is radially arranged.

Further, the inlet pipe and the outlet pipe are arranged in parallel.

Compared with the prior art, the utility model has the characteristics of it is following: the utility model discloses a separation blade makes the load outside form refrigerant liquid face, and the refrigerant falls perpendicularly from the clearance, and the refrigerant gasifies rapidly, improves refrigeration efficiency, reduces the thermal resistance, and it is extravagant to reduce the material, and the refrigerant gasification makes conduction efficiency improve greatly, makes the load can cool down rapidly.

Drawings

Fig. 1 is a schematic perspective view of the evaporator of the flake ice maker of the present invention.

Fig. 2 is a schematic longitudinal sectional structure diagram of the evaporator of the flake ice maker of the present invention.

Fig. 3 is a schematic diagram of a transverse cross-sectional structure of an evaporator of the flake ice machine of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the following embodiments. In the following description, any concept relating to the directions or orientations of up, down, left, right, front, and rear is given with respect to the position shown in the drawings being described, and thus should not be construed as particularly limiting the technical solution provided by the present invention.

As shown in fig. 1 to 3, the evaporator of the flake ice maker of the present invention comprises an inner tube 1, a coaxial cover is provided on the outer tube 2 of the inner tube 1, which is arranged on the upper plate 3 of the upper end of the inner tube 1, and which is arranged on the lower plate 4 of the lower end of the inner tube 1, the length of the inner tube 1 is larger than that of the outer tube, the outer tube 2, the upper plate 3 and the lower plate 4 are welded outside the inner tube 1, the sealed space enclosed by the inner tube 1, the outer tube 2, the upper plate 3 and the lower plate 4 forms an evaporation chamber, and the evaporation chamber is arranged outside the load of the flake ice maker, so that the refrigerant in the evaporation chamber is gasified to greatly improve the conduction efficiency in the load.

An inlet pipe 5 for a refrigerant to flow in and an outlet pipe 6 for the refrigerant to flow out are arranged on the outer cylinder 2, the inlet pipe 5 and the outlet pipe 6 are both communicated with the evaporation chamber and are both arranged at the upper end of the evaporation chamber, and the pipe diameter of the outlet pipe 6 is larger than that of the inlet pipe 5; the inside of the evaporation chamber is provided with a separation blade 7, as shown in fig. 2 and 3, the separation blade 7 is close to the top of the evaporation chamber, the inlet pipe 5 is arranged above the separation blade 7, the separation blade 7 is fixedly arranged on the outer barrel 2, so that the refrigerant falls onto the separation blade 7, the separation blade 7 surrounds the inner wall of the outer barrel 2, a gap 72 is arranged between the separation blade and the inner barrel, the refrigerant flows onto the separation blade 7 through the inlet pipe 5 and falls from the gap between the separation blade and the inner barrel to form a waterfall, the refrigerant is rapidly gasified when falling down, the heat in the load is absorbed, the evaporation refrigeration is realized, and the refrigeration efficiency is improved.

The baffle is arranged at 1/9-1/7 of the evaporation chamber (namely, at 1/9-1/7 of the height of the evaporation chamber), and preferably, the baffle is arranged at 1/8 of the evaporation chamber, so that the baffle is at enough height to ensure that the refrigerant can be completely gasified, and the refrigerant is prevented from accumulating at the bottom of the evaporation chamber while still in a liquid state.

The separation blade is the annular setting, and is planar, in some embodiments, can also set up the baffle at the inboard edge of separation blade to guide refrigerant liquid to the end of keeping away from into the pipe, make refrigerant evenly distributed outside the inner tube, evenly seted up a plurality of opening certainly on this baffle, make the refrigerant evenly fall from the opening part.

Of course, the baffle plate can also be in a spiral shape, and the inlet pipe is arranged at the high position of the baffle plate to play a role of guiding the refrigerant, so that the refrigerant is uniformly distributed outside the inner cylinder.

The baffle 7 is provided with a notch 71 for allowing the gas vaporized from the refrigerant to pass through, and the outlet pipe is arranged above the notch 71 for allowing the gas to flow out from the outlet pipe.

The outlet pipe is arranged in the radial direction, the inlet pipe and the outlet pipe are arranged in parallel, and the inlet pipe extends into the evaporation chamber to play a better guiding role.

When the evaporator works, a refrigerant enters the evaporation chamber from the inlet pipe 5, flows along the baffle 7, and when the baffle flows, the refrigerant vertically falls from a gap between the baffle 7 and the inner cylinder 1, and is gasified when falling, so that heat loaded in the inner cylinder is absorbed, and the gasified refrigerant rises from the notch 71 and then flows out from the outlet pipe 6. The utility model discloses an evaporator simple structure refrigerates soon, and is efficient, and with low costs.

Finally, it should be noted that: the above embodiments are merely illustrative of the technical solutions of the present invention, and not limitative thereof; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications or substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. An ice flake machine evaporator is characterized in that: the ice flake machine comprises a load and an evaporator arranged outside the load, wherein the evaporator comprises an evaporation chamber surrounding the outer side of the load, an inlet pipe for introducing a refrigerant and an outlet pipe for leading out refrigerant gas, a separation blade is arranged in the evaporation chamber, the separation blade is arranged on the outer wall of the evaporation chamber, the inlet pipe is arranged above the separation blade, and a gap is arranged between the separation blade and the inner wall of the evaporation chamber so that the refrigerant can fall down from the gap.

2. An evaporator of a flake ice machine as set forth in claim 1 wherein the baffle is near the top of the evaporation chamber.

3. An evaporator of a slice ice machine as claimed in claim 1 or 2, characterized in that the baffle is arranged at 1/9-1/7 of the evaporation chamber.

4. An evaporator of a flake ice machine as claimed in claim 3 wherein the baffle is preferably disposed at 1/8 of the evaporation chamber.

5. The evaporator of the slice ice machine as claimed in claim 1, wherein the baffle is provided with a notch, and the outlet pipe is arranged above the notch.

6. The evaporator of claim 1, wherein the inlet tube extends into the evaporation chamber.

7. The evaporator of the flake ice machine as claimed in claim 1, wherein the baffle is planar.

8. The evaporator of the flake ice machine as claimed in claim 1, wherein the baffle is spiral.

9. The evaporator of claim 1, wherein the exit tube is radially disposed.

10. The evaporator of the flake ice machine as claimed in claim 9, wherein the inlet tube and the outlet tube are arranged in parallel.

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