CN115183505A - Evaporator of stainless steel ice maker - Google Patents

Abstract

The invention discloses an evaporator of a stainless steel ice maker, belonging to the technical field of refrigeration equipment. The stainless steel ice maker evaporator comprises a plurality of groups of stainless steel pipes which are arranged in parallel side by side, each group of stainless steel pipes comprises a cavity and an outer surface, the cavity comprises a bottom cavity in the XY plane direction and a side cavity in the plane direction intersecting with the XY plane, the side cavity protrudes out of the bottom cavity in the plane direction of the side cavity, at least one side of the four directions of the outer surface is provided with a bottom surface in the XY plane direction and an ice making side surface in the plane direction intersecting with the XY plane, and the ice making side surface protrudes out of the bottom surface in the plane direction of the ice making side surface. The bottom surface and the ice making side surface enclose a second cavity. According to the evaporator of the stainless steel ice maker, the evaporator body is made of the stainless steel material completely, the manufacturing process is simple, an electroplated layer is not needed, the ice template and the refrigerant flowing space are ensured to be tightly connected, the cost is low, the ice making effect is good, and the ice making efficiency is high.

Description

Evaporator of stainless steel ice maker

Technical Field

The invention relates to the technical field of refrigeration equipment, in particular to an evaporator of a stainless steel ice maker.

Background

An ice maker is a refrigeration machine that produces ice by cooling water through an evaporator with a refrigerant in a refrigeration system. The shapes of the generated ice are different according to different principles of evaporators and generation processes, and people generally divide ice machines into a particle ice machine, a flake ice machine, a plate ice machine, a tube ice machine, a shell ice machine and the like according to the shapes of the ice. The running water type oblique ice is most popular in the market and widely applied.

The evaporator is used as an important component in the ice maker, the principle is that high-pressure refrigerant liquid is evaporated in the evaporation pipe through the throttling device, the evaporation pipe absorbs heat to achieve the refrigeration effect, and the evaporation pipe transmits cold energy to the ice template in the ice maker, so that water flowing into the ice template is frozen to form ice blocks, and the ice maker can be used.

The existing ice-making evaporator for making the ice cubes still has the following problems:

the main structure of the existing ice-making evaporator is a copper part, the manufacturing cost is high, the copper part needs to be electroplated by metals such as nickel, and the like, an electroplated layer is easy to fall off after being used for a long time, and the electroplating mode is difficult to pass food safety detection;

the evaporating pipe all coils in the chassis bottom of ice template, is located the back on the chassis for the ice tray promptly, through the indirect ice cube tray heat transfer that gives of chassis, in order to ensure that the evaporating pipe can be reliable with the refrigeration of ice template, so will ensure evaporating pipe and the compactness of ice template when making the assembly, in the prior art, the manufacturing process at this department is: and coating solder paste on the part to be welded between the evaporation tube and the ice template, clamping the copper tube and the ice template by using a clamp, heating in a heating furnace, taking out after heating for a certain time at a specified temperature, cooling, and cleaning by using a reagent.

Although the welding assembly process can ensure the tight connection between the ice template and the evaporation tube, the welding assembly process has the defects of complex process and high process requirement.

For solving with copper spare, the technology is complicated, and is with high costs, and probably there is the problem that is difficult to pass through food safety inspection, the current publication number is CN 208735984U's novel ice machine aluminium system evaporimeter ice dish, copper pipe inslot installation copper pipe, the ice dish adopts aluminium system, be favorable to the wastrel to retrieve more environmental protection and convenient, the preparation technology is faster and simple, but refrigerant flow pipeline adopts different materials preparation respectively with the ice dish, and refrigerant flow pipeline still adopts copper spare, still exists welding assembly technology complicacy to a certain extent, problem with high costs.

Therefore, there is a need to provide an evaporator for an ice maker made of stainless steel to solve the above-mentioned problems.

Disclosure of Invention

The invention aims to provide a stainless steel ice maker evaporator, which solves the problems of complex welding and assembling process and high cost of a copper evaporator.

In order to achieve the purpose, the evaporator of the stainless steel ice maker comprises an evaporator body, wherein the evaporator body is made of stainless steel materials completely.

Preferably, the stainless steel evaporator of the ice maker comprises a plurality of groups of stainless steel pipes which are arranged in parallel side by side, each group of stainless steel pipes comprises a cavity and an outer surface, the cavity comprises a bottom cavity in an XY plane direction and a side cavity in a plane direction intersecting with the XY plane, the side cavity protrudes out of the bottom cavity in the plane direction, at least one side of four positions of the outer surface is provided with a bottom surface in the XY plane direction and an ice making side surface in the plane direction intersecting with the XY plane, and the ice making side surface protrudes out of the bottom surface in the plane direction.

Preferably, the bottom surface and the ice making side surface enclose a second cavity, and a cutting section of the second cavity along the YZ direction includes a shortest bottom edge.

Preferably, each group of the stainless steel pipes is an integrally formed special pipe.

Preferably, each group of the stainless steel pipes are arranged by combining square pipes and/or trapezoidal pipes and/or triangular pipes.

Preferably, the mechanical tubes include a first outer side surface and a second outer side surface, the first outer side surface is an outermost side surface on one side of the ice making side surface, the second outer side surface is an outermost side surface on the opposite side, short notches are alternately formed on the first outer side surface and the second outer side surface in the left-right direction, the height of the upper edge of each short notch is not higher than the height of the bottom surface, and the left-right positions of the short notches of the first outer side surface and the second outer side surface adjacent to each other are alternately formed again.

Preferably, each group of stainless steel pipes is arranged by combining a square pipe and/or a trapezoid pipe and/or a triangular pipe, the combined structure comprises a third outer side surface on the outermost side, a fourth outer side surface on the side corresponding to the third outer side surface and a middle connecting surface positioned between the third outer side surface and the fourth outer side surface, short notches are sequentially arranged on the third outer side surface, the middle connecting surface and the fourth outer side surface in a left-right alternating mode, and the height of the upper edge of each short notch is not higher than that of the bottom surface.

Preferably, the two ends of the stainless steel pipe are provided with a left end socket and a right end socket, the left end socket and the right end socket are hermetically connected with the end parts of the surfaces of the stainless steel pipe except the short gap, the upper end parts or the lower end parts of a plurality of groups of stainless steel pipes of the evaporator of the ice maker are provided with partition plate strips, and the two ends of the inner closed space of the stainless steel pipes are communicated with the refrigerant inlet pipe and the refrigerant outlet pipe.

Preferably, the stainless steel ice making machine further comprises a plurality of longitudinal separation pieces which are arranged in parallel, each longitudinal separation piece comprises clamping grooves which are consistent with the ice making side faces of the stainless steel pipes in number, the longitudinal separation pieces are divided into a plurality of clamping pieces, the clamping grooves are clamped on the ice making side faces and the adjacent faces of the ice making side faces, the depth of each clamping groove is based on the fact that the bottom of each longitudinal separation piece is in contact with the bottom face when the clamping groove is clamped and installed, and at least one corner of the bottom of each clamping piece is provided with an arc notch.

Preferably, indulge the both ends of spacer and set up the trip strip, the upper end of trip strip with indulge spacer fixed connection, the lower extreme sets up inward trip, the upper and lower end stainless steel outside bottom of stainless steel ice maker evaporimeter set up with the many pairs of second draw-in grooves that the trip corresponds, the trip strip is elastic construction spare, still includes arm and power component and controller, the arm with indulge the spacer and be connected, controller control power component does the arm provides the messenger indulge the spacer upwards lifts up and the power of joint downwards.

Preferably, the edge of the hook is provided with a smooth clamping surface, and the edge of the second slot is also provided with a smooth clamping surface.

Preferably, the natural inner edge distance of the trip strips at the two sides of the longitudinal separation piece is smaller than the minimum distance between the stainless steel outer sides of the upper end and the lower end of the stainless steel ice maker evaporator.

Preferably, the upper part of each longitudinal separation piece is provided with a connecting plate, and the connecting plate is connected with the mechanical arm.

Arrange through multiunit stainless steel tubular product and assemble the setting, make evaporimeter structure standardized, the process simplification is streamlined, through every stainless steel tubular product lateral part cavity of group, the bottom cavity, bottom surface and the ingenious setting of ice-making side and refrigerant passageway, improve the heat conduction efficiency of ice-making, can reach the heat conduction efficiency that surpasss the copper part even when avoiding the complicated technology of copper part, combine the structure application of longitudinal separation piece and arm, improve the speed of unloading ice through partial mechanical ice-unloading, compensate the reverse heat-conduction difference of stainless steel tubular product and copper part, improve the rotation rate of evaporimeter, and then improve ice-making efficiency.

Compared with the prior art, the evaporator of the stainless steel ice maker has the following beneficial effects:

according to the evaporator of the stainless steel ice maker, the evaporator body is made of the stainless steel material completely, the manufacturing process is simple, an electroplated layer is not needed, the ice template is ensured to be tightly connected with a refrigerant flowing space, the cost is low, the ice making effect is good, and the ice making efficiency is high.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural view of a first embodiment of a stainless steel ice maker evaporator provided in accordance with the present invention;

fig. 2 is an exploded view of a second embodiment of a stainless steel ice maker evaporator provided by the present invention;

fig. 3 is a schematic cross-sectional view of the stainless steel ice maker evaporator provided by the present invention;

FIG. 4 isbase:Sub>A sectional view taken along line A-A of FIG. 3;

fig. 5 is a schematic structural view of the profile tube of fig. 2;

fig. 6 is a schematic diagram of an arrangement structure of a plurality of groups of special pipes in fig. 2;

fig. 7 is a schematic cross-sectional view of a third embodiment of an ice maker evaporator made of stainless steel in accordance with the present invention;

FIG. 8 is a sectional view taken along line B-B of FIG. 7;

FIG. 9 is a schematic structural view of the trapezoidal tube of FIG. 7;

FIG. 10 is a schematic view of the right angle triangular tube of FIG. 7;

fig. 11 is a schematic cross-sectional view of a fourth embodiment of an ice maker evaporator made of stainless steel in accordance with the present invention;

fig. 12 is a schematic structural view of a fifth embodiment of a stainless steel ice maker evaporator provided by the present invention;

fig. 13 is a schematic view of the longitudinal partition of a fifth embodiment of the stainless steel ice maker evaporator provided by the present invention;

the reference numbers in the figures:

1. an evaporator body, 2, a bottom surface, 3, an ice-making side surface, 4, a second cavity,

5. a profiled tube, 501, a first outer side, 502, a second outer side,

6. left and right end sockets 7, a cavity 8, a short gap 9 and a clapboard strip,

10. longitudinal septa, 101, card slots, 102, cards,

11. a trapezoid pipe 111, an inclined surface of the trapezoid pipe 112, a lower bottom surface of the trapezoid pipe,

12. a right-angled triangular tube 121, an inclined plane of the right-angled triangular tube,

13. a third outer side 14, a fourth outer side 15, an intermediate connecting surface,

16. an isosceles trapezoid pipe 161, the waist surface of the isosceles trapezoid pipe 162, the lower bottom surface of the isosceles trapezoid pipe 163, the upper bottom surface of the isosceles trapezoid pipe,

17. an isosceles triangular tube 171, a waist surface of the isosceles triangular tube 172, a bottom surface of the isosceles triangular tube 173, an upper tip portion of the isosceles triangular tube,

18. an S-shaped channel 19, a refrigerant inlet pipe and a refrigerant outlet pipe,

20. a clamping hook strip 201, a clamping hook 202 and a clamping surface,

21. a connecting bottom plate 211 and a second card slot,

22. a connecting plate.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

First embodiment

The stainless steel evaporator of the ice maker as shown in fig. 1 comprises an evaporator body 1, wherein the evaporator body 1 is made of stainless steel materials completely, the stainless steel evaporator comprises a plurality of groups of stainless steel pipes which are arranged in parallel side by side, each group of stainless steel pipes comprises a cavity and an outer surface, the cavity comprises a bottom cavity in an XY plane direction and a side cavity in a plane direction intersecting with the XY plane, the side cavity protrudes out of the bottom cavity in the plane direction, at least one side of four directions of the outer surface is provided with a bottom surface 2 in the XY plane direction and an ice making side surface 3 in the plane direction intersecting with the XY plane, the ice making side surface 3 protrudes out of the ice making bottom surface 2 in the plane direction, the bottom surface 2 and the outer side of the ice making side surface 3 are combined to form a second cavity 4 for making ice, and the cutting section of the second cavity 4 in a YZ direction comprises the shortest bottom edge. The refrigerant is introduced into the cavity, the second cavity 4 carries out multidirectional direct stainless steel refrigeration conduction at the bottom and the side part, the direct refrigeration conduction area is increased under the same ice making area, the heat conduction efficiency is improved, and the evaporator body is made of stainless steel materials completely to become a practical and feasible manufacturing process.

Compared with the prior art, the evaporator of the stainless steel ice maker provided by the invention has the following beneficial effects:

the evaporator body is made of stainless steel materials completely, the manufacturing process is simple, an electroplated layer is not needed, tight connection of the ice template and a refrigerant flowing space is guaranteed, the cost is low, the ice making effect is good, and the ice making efficiency is high.

Second embodiment

Referring to fig. 2, fig. 3, fig. 4, fig. 5 and fig. 6, a second embodiment of the present application is another evaporator based on the evaporator provided by the first embodiment of the present application. The second embodiment is only the preferred mode of the first embodiment, and the implementation of the second embodiment does not affect the implementation of the first embodiment alone.

Specifically, the evaporator provided in the second embodiment of the present application is different in that the evaporator body includes a plurality of sets of stainless steel pipes arranged in parallel side by side, and each set of stainless steel pipes is an integrally formed special pipe 5.

The special pipe 5 comprises a first outer side surface 501 and a second outer side surface 502, the first outer side surface 501 is the outermost side surface on one side of the ice making side surface 3, the second outer side surface 502 is the outermost side surface on the opposite side, short notches 8 are alternately arranged on the first outer side surface 501 and the second outer side surface 502 from left to right, the height of the upper edge of each short notch 8 is not higher than that of the bottom surface 2, and the left and right positions of the short notches 8 on the first outer side surface 501 and the second outer side surface 502 of the adjacent special pipe 5 are alternately arranged again. The two end parts of the stainless steel pipe are provided with a left end socket 6 and a right end socket 6, the left end socket 6 and the right end socket 6 are in sealing connection with the end parts of the stainless steel pipe except the short notch 8, so that the cavity 7 forms an S-shaped channel 18 for introducing a refrigerant to directly conduct cold in multiple directions to the bottom surface 2 and the ice making side surface 3. The upper end and the lower end of a plurality of groups of stainless steel pipes of the evaporator of the stainless steel ice maker are provided with partition plate strips 9 to seal short gaps 8 at the ends and assist in forming a complete ice tray structure. The two ends of the inner closed space of the multiple groups of stainless steel pipes are communicated with the refrigerant inlet and outlet pipes 19, only the direct heat conduction of the stainless steel plate surface is realized between the refrigerant and the ice making surface, the contact is more sufficient, the heat conduction utilization rate is high, and the heat conduction efficiency meets the industrial requirement of the ice making efficiency.

The ice tray of the evaporator is provided with a plurality of longitudinal separation sheets 10 which are arranged in parallel, each longitudinal separation sheet 10 comprises clamping grooves 101 the number of which is consistent with that of ice making side surfaces 3 of a plurality of groups of stainless steel pipes, the longitudinal separation sheets 10 are divided into a plurality of clamping pieces 102, the clamping grooves 101 are clamped on the ice making side surfaces 3 and the adjacent surfaces of the ice making side surfaces, the depth of each clamping groove 101 is based on the fact that the bottom of each longitudinal separation sheet 10 contacts with the bottom surface 2 when the clamping pieces are installed, and at least one corner of the bottom of each clamping piece 102 is provided with an arc notch.

Third embodiment

Referring to fig. 7, 8, 9 and 10, a third embodiment of the present application is directed to another evaporator based on the evaporator provided by the first embodiment of the present application. The third embodiment is merely a preferred mode of the first embodiment, and the implementation of the third embodiment does not affect the implementation of the first embodiment alone.

Specifically, the evaporator provided in the third embodiment of the present application is different in that each set of the stainless steel pipes is provided by combining a trapezoidal pipe 11 and a right-angled triangular pipe 12. The inclined plane 121 of right angle triangle-shaped pipe and the inclined plane 111 welded connection of trapezoidal pipe, the right-angle face 123 of right angle triangle-shaped pipe and the lower bottom surface 112 coplane setting of trapezoidal pipe form integrated configuration. The integrated configuration includes the third lateral surface 13 (the right-angle face of trapezoidal pipe) in the outside and corresponds the fourth lateral surface 14 (another right-angle face of right-angle triangular pipe) of side with it and is located third lateral surface 13 with intermediate junction face 15 (the inclined plane of right-angle triangular pipe and the inclined plane of trapezoidal pipe) between the fourth lateral surface 14, third lateral surface 13, intermediate junction face 15 with fourth lateral surface 14 controls in proper order and sets up short breach 8 in turn, the last border height of short breach 8 is not higher than the height of bottom surface 2. The both ends of stainless steel tubular product set up about the head, about the head with stainless steel tubular product except that short breach 8 face end sealing connection, make cavity 7 form and loop through trapezoidal pipe 11 and the S-shaped passageway 18 of right angle triangle venturi tube 12 for let in the refrigerant and directly cool the conduction to diversified in bottom surface 2 and the system ice side 3. The upper end and the lower end of a plurality of groups of stainless steel pipes of the evaporator of the stainless steel ice maker are provided with baffle strips for sealing the short gaps 8 at the ends and assisting in forming a complete ice tray structure. The both ends intercommunication refrigerant business turn over pipe 19 of the inside enclosure space of multiunit stainless steel tubular product, upper portion sets up a plurality of parallel arrangement's vertical spacer 10, and only the direct heat-conduction of stainless steel plate face between refrigerant and the ice-making face contacts more fully, and heat-conduction utilization ratio is high, and heat-conduction efficiency satisfies the industrialization demand of ice-making efficiency.

Fourth embodiment

Referring to fig. 11, a fourth embodiment of the present application provides another evaporator based on the evaporator provided in the first embodiment of the present application. The fourth embodiment is only a preferable mode of the embodiment, and the implementation of the fourth embodiment does not affect the implementation of the first embodiment alone.

Specifically, the evaporator provided in the fourth embodiment of the present application is different in that each group of the stainless steel pipes is provided by combining an isosceles trapezoid pipe 16 and an isosceles triangle pipe 17. The waist surface 161 of the isosceles trapezoid pipe is connected with the waist surface 171 of the isosceles triangle pipe in a face-to-face manner, the lower bottom surface 162 of the isosceles trapezoid pipe is coplanar with the bottom surface 172 of the isosceles triangle pipe, and the upper tip 173 of the isosceles triangle pipe protrudes out of the upper bottom surface 163 of the isosceles trapezoid pipe, so that a combined structure is formed. The combined structure comprises a third outer side surface 13 (a non-connection waist surface of an isosceles trapezoid tube) on the outermost side, a fourth outer side surface 14 (a non-connection waist surface of an isosceles triangle tube) on the side corresponding to the third outer side surface 13, and a middle connection surface 15 (a connection waist surface of the isosceles triangle tube and a connection waist surface of the isosceles trapezoid tube) between the third outer side surface 13 and the fourth outer side surface 14, wherein short notches 8 are alternately arranged on the third outer side surface 13, the middle connection surface 15 and the fourth outer side surface 14 in a left-right mode in sequence, and the height of the upper edge of each short notch 8 is not higher than that of an upper bottom surface 163 of the isosceles trapezoid tube. The two end parts of the stainless steel pipe are provided with a left end socket and a right end socket, the left end socket and the right end socket are in sealing connection with the end parts of the stainless steel pipe except the short gaps, so that the cavity 7 forms an S-shaped channel 18 sequentially passing through the isosceles trapezoid pipe 16 and the isosceles triangle pipe 17 and is used for introducing a refrigerant to carry out multidirectional direct cold conduction on the bottom surface 2 and the ice making side surface 3. The upper end and the lower end of a plurality of groups of stainless steel pipes of the evaporator of the stainless steel ice maker are provided with baffle strips for sealing the short gaps 8 at the ends and assisting in forming a complete ice tray structure. The both ends intercommunication refrigerant business turn over pipe 19 of the inside enclosure space of multiunit stainless steel tubular product, upper portion sets up a plurality of parallel arrangement's vertical spacer 10, and only the direct heat-conduction of stainless steel plate face between refrigerant and the ice-making face contacts more fully, and heat-conduction utilization ratio is high, and heat-conduction efficiency satisfies the industrialization demand of ice-making efficiency.

Fifth embodiment

Referring to fig. 12 and 13 in combination, a fifth embodiment of the present application is directed to another evaporator based on the evaporator provided by the first embodiment of the present application. The fifth embodiment is merely a preferred mode of the embodiment, and the implementation of the fifth embodiment does not affect the implementation of the first embodiment alone.

Specifically, the difference that the evaporimeter that this application's fifth embodiment provided lies in, and trip strip 20 is set up at the both ends of the piece 10 that indulges of evaporimeter, trip strip 20 the upper end with piece 10 fixed connection indulges, and the lower extreme sets up inward trip 201, and trip 201's card limit portion sets up slick and sly joint face 202, stainless steel machine evaporimeter's upper and lower end stainless steel outside bottom sets up connecting bottom plate 21, connecting bottom plate 21 go up set up with trip 201 corresponds many pairs of second draw-in groove 211, the card limit portion of second draw-in groove 211 also sets up slick and sly joint face 202. The trip strips 20 are elastic structural members, and the natural inner edge distance of the trip strips 20 at two sides of the longitudinal separation sheet 10 is smaller than the minimum distance between the outer sides of stainless steel at the upper end and the lower end of the evaporator of the stainless steel ice maker.

When the longitudinal separation piece 10 is clamped on the ice tray, the clamping hook strips 20 on two sides have the functions of locking and fixing the position of the ice tray, each group of clamping hooks 201 is clamped into the second clamping groove 211, the second clamping grooves 211 limit the clamping hooks 201, the position of the longitudinal separation piece 10 is locked, and the size and the shape of the ice block are controlled and stabilized to be even and fixed.

Every vertical spacer 10's upper portion sets up connecting plate 22, and connecting plate 22 connects the arm, and power component and controller are connected to the arm, and the controller control power component does the arm provides the messenger vertical spacer 10 upwards lifts up and the power of joint down. When ice is removed, the controller controls the power assembly to provide power to drive the mechanical arm to lift the longitudinal separation piece 10, the hook strip 20 drives the hook 201 to be separated from the second clamping groove 211, the longitudinal separation piece 10 is stripped from an ice block, the evaporator is enabled to be rapidly removed from ice, and the evaporator enters the next ice making procedure. The stainless steel ice maker evaporator in the whole ice making process does not need reverse heat conduction, the reverse heat conduction difference between the stainless steel pipe and the copper part is compensated, the rotation rate of the evaporator is improved, the ice making efficiency is further improved, the structure of the stainless steel evaporator is standardized, the process is simplified and is streamlined, and the cost is low.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. The utility model provides an ice maker evaporimeter is made to stainless steel, includes the evaporimeter body, its characterized in that: the evaporator body is made of stainless steel materials completely.

2. An ice maker evaporator according to claim 1 wherein: the stainless steel ice maker evaporator comprises a plurality of groups of stainless steel pipes which are arranged in parallel side by side, each group of stainless steel pipes comprises a cavity and an outer surface, the cavity comprises a bottom cavity in an XY plane direction and a side cavity in a plane direction intersecting with the XY plane, the side cavity protrudes out of the bottom cavity in the plane direction, at least one side of four positions of the outer surface is provided with a bottom surface in the XY plane direction and an ice making side surface in the plane direction intersecting with the XY plane, and the ice making side surface protrudes out of the bottom surface in the plane direction of the ice making side surface.

3. An ice maker evaporator according to claim 2 wherein: the bottom surface and the outer side of the ice making side surface enclose a second cavity, and the cutting section of the second cavity along the YZ direction comprises the shortest bottom edge.

4. An ice maker evaporator according to claim 2 wherein: each group of stainless steel pipes are special pipes which are integrally formed.

5. The stainless steel ice maker evaporator of claim 2 wherein: each group of stainless steel pipes are combined through square pipes and/or trapezoidal pipes and/or triangular pipes.

6. An ice maker evaporator according to claim 4 wherein: the special pipe comprises a first outer side face and a second outer side face, the first outer side face is the outermost side face on one side of the ice making side face, the second outer side face is the outermost side face on the opposite side, short notches are alternately arranged on the first outer side face and the second outer side face from left to right, the height of the upper edge of each short notch is not higher than that of the bottom face, and the left and right positions of the short notches adjacent to the first outer side face and the second outer side face of the special pipe are alternately arranged again.

7. An ice maker evaporator according to claim 5 wherein: each group of stainless steel pipes are arranged through one or two combinations of square pipes and/or trapezoidal pipes and/or triangular pipes, each combined structure comprises a third outer side face on the outermost side, a fourth outer side face on the side corresponding to the third outer side face and a middle connecting face located between the third outer side face and the fourth outer side face, short notches are formed in the third outer side face, the middle connecting face and the fourth outer side face in a left-right alternating mode in sequence, and the height of the upper edge of each short notch is not higher than that of the bottom face.

8. An ice maker evaporator according to any one of claims 6 or 7 wherein: the two ends of the stainless steel pipe are provided with a left sealing head and a right sealing head, the left sealing head and the right sealing head are connected with the end parts of the stainless steel pipe except the short gap in a sealing manner, the upper end parts or the lower end parts of a plurality of groups of stainless steel pipes of the evaporator of the stainless steel ice maker are provided with partition plate strips, and the two ends of the inner closed space of the plurality of groups of stainless steel pipes are communicated with a refrigerant inlet pipe and a refrigerant outlet pipe.

9. An ice maker evaporator of stainless steel as claimed in any one of claims 2 wherein: the stainless steel ice making device is characterized by further comprising a plurality of longitudinal separation pieces which are arranged in parallel, each longitudinal separation piece comprises a plurality of clamping grooves which are consistent with the ice making side surfaces of the stainless steel pipes in number, the longitudinal separation pieces are divided into a plurality of clamping pieces, the clamping grooves are clamped on the ice making side surfaces and the adjacent surfaces of the ice making side surfaces, the bottom of each longitudinal separation piece is in contact with the bottom surface as a standard when the clamping grooves are clamped and installed, and at least one corner of the bottom of each clamping piece is provided with an arc-shaped notch.

10. An ice maker evaporator according to any one of claims 9 wherein: indulge the both ends of spacer and set up the trip strip, the upper end of trip strip with indulge spacer fixed connection, the lower extreme sets up inside trip, the upper and lower end stainless steel outside bottom of nonrust steel ice maker evaporimeter set up with the second draw-in groove that the trip corresponds, the trip strip is elastic construction spare, still includes arm and power component and controller, the arm with indulge the spacer and connect, controller control power component does the arm provides the messenger indulge the spacer upwards lift up and the power of joint downwards.

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