JP2001029705A - Solid-liquid separator for ice slurry - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent clogging of a filter. SOLUTION: In a solid-liquid separator 1 wherein while an ice slurry 10 containing ice as a solid content is transferred along an inner face of a filter 3, a liquid content in the slurry 10 is continuously separated via the filter 3 and taken outside, a contact type heating means 5 is provided, which comprises a cylindrical retaining wall (casing) 5A enclosing the whole outer peripheral face of the filter 3 at a specific interval to the outer face of the filter 3, an air duct line 5B communicating to the inside of the cylindrical retaining wall 5A, a fan 5C which is connected to the other end of the air duct 5B and supplied air into the cylindrical retaining wall 5A via inside the pipe line 5B, and a heater 5D which is installed to the air duct line 5B and heats air passing through the duct line 5B. The filter is suitably a metal-made filter.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solid-liquid separation device for separating a liquid component in an ice slurry through a filter.

[0002]

2. Description of the Related Art There are various methods for extracting only ice from an ice slurry containing ice as a solid content. For example, solid-liquid separation of the ice slurry becomes possible by separating the liquid component in the ice slurry through a filter.

[0003]

However, when the present inventor conducted such a solid-liquid separation experiment, ice adhered to the filter, which caused clogging of the filter and reduced separation efficiency. It has been found that various problems occur.

Accordingly, a main object of the present invention is to prevent ice from adhering to a filter.

[0005]

According to the present invention, there is provided a solid-liquid separation apparatus for ice slurry, which separates a liquid component in ice slurry containing ice as a solid component through a filter. An apparatus for separating ice, comprising means for preventing ice from adhering to the filter.

[0006] The apparatus of the present invention may be provided with a heating means for directly or indirectly heating the ice adhering to the filter or the ice in contact with the filter as the ice adhesion preventing means. As a means, the filter may be provided with a water-repellent coat.

<Action> As is well known, the surface of ice has a feature that it easily adheres to other solids because it repeatedly melts and solidifies. In addition, since the filter surface is formed with a permeation hole and is not smooth, it has high adhesion. Therefore, when the liquid component in the ice slurry is separated through the filter, the ice adheres to the filter from the inside. Further, other ice may adhere to the adhered ice and be integrated. As a result of such icing, various problems (other problems will be described later) such as clogging of the filter and reduction of the separation efficiency occur.

However, according to the present invention, if an ice adhesion preventing means for preventing ice from adhering to the filter, for example, a heating means for heating ice near the filter as described in an embodiment to be described later, is provided, Thus, problems such as filter clogging can be solved. The term "preventing ice from adhering to the filter" in the present invention includes not only preventing ice from adhering to the filter, but also removing ice adhering to the filter from the filter by melting or the like.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The solid-liquid separation apparatus of the present invention is a batch type in which the liquid remaining in an ice slurry is separated through a filter and then ice remaining on the inner surface of the filter is removed. It also includes a method in which an ice slurry containing solids is transferred along a filter surface and a liquid component in the slurry is continuously separated through a filter.

However, especially in the case of such a continuous type, as the ice slurry passes through the filter surface, the liquid content decreases and the ice content increases, so that the transfer resistance increases, and the transfer speed decreases accordingly. For this reason, even if the ice slurry is transported along the filter surface, ice components easily adhere to the filter surface. In addition, the transfer energy consumed increases, including the further increase in the transfer resistance of the ice slurry due to the icing.

On the other hand, in a continuous solid-liquid separation apparatus for transferring an ice slurry containing ice as a solid component along a filter surface and continuously separating a liquid component in the slurry through a filter. By providing an ice adhesion preventing means for preventing ice from adhering to the filter, an increase in the transfer resistance of the ice slurry can be prevented.

Hereinafter, an embodiment of such a continuous solid-liquid separation device will be described in detail with reference to the accompanying drawings. However, as described above, the present invention is not limited to a continuous type, and may be applied to a batch type device. Can be.

<First Embodiment> FIG. 1 shows an example 1 of a solid-liquid separation device for ice slurry according to a first embodiment, which is a transfer line 2 for ice slurry and a transfer line 2 for the ice slurry. 2 is provided with a tubular filter 3 connected to the downstream side of the filter 2 and a residual ice transfer line 4 connected to the downstream side of the tubular filter 3, and an ice slurry 10 containing ice as a solid content is provided on the inner surface of the filter 3. While being transported along, the liquid component in the slurry 10 is continuously separated via the filter 3 and taken out to the outside.

In the solid-liquid separator 1, as a means for preventing ice adhesion of the present invention, a cylindrical retaining wall (casing) 5A surrounding the entire outer peripheral surface of the filter 3 at a predetermined distance from the outer surface of the filter 3; A blower duct 5B communicating with the inside of the tubular retaining wall 5A, a fan 5C connected to the other end of the blower duct 5B and supplying air into the tubular retaining wall 5A via the inside of the duct; And a heater 5D mounted on the passage 5B for heating air passing through the conduit. Preferably, the filter 3 is a metal filter (same as the following embodiment).

When performing solid-liquid separation in such an apparatus,
The fan 5C is started, and the warm air or the heated gas (hereinafter, referred to as warm air) heated by the heater 5D is supplied to the cylindrical retaining wall 5.
Send it into A. The warm air sent into the cylindrical retaining wall 5A contacts the filter surface as shown by the two-dot chain line arrow, rises while warming the filter surface, and is discharged from the opening 5E above the cylindrical retaining wall 5A. Therefore, in this case, the filter surface can always be warmed with new warm air.

Simultaneously with or after this, while hot air is being continuously blown, an ice slurry 10 containing ice as a solid component is supplied to the filter 3 side through a slurry transfer pipe 2 by a pressure pump (not shown). Continuous supply. The supplied slurry 10 is sequentially transferred into the filter 3 by the supply pressure of the subsequent slurry which is sequentially fed, and in the process of being transferred along the inner surface of the filter 3, as shown by a solid arrow, the liquid content of the slurry 10 is sequentially reduced. Are continuously separated through the filter 3 and taken out. Reference numeral 11 denotes a slurry from which a liquid component has been separated to some extent. The residual ice 12 that has passed through the filter 3 (actually, not all of the liquid is separated and removed, but ice containing a slight amount of liquid) is taken out through the residual ice transfer line 4.

If the above-mentioned hot air blowing is not performed, ice adheres to and grows on the inner surface of the filter 3 during the transfer of the ice slurry 10 along the filter 3, causing the filter 3 to be clogged. Become. However, if the filter 3 is warmed by blowing hot air, even if the ice transferred along the filter 3 comes into contact with the inner surface of the filter 3,
Alternatively, even if it is instantaneously attached to the filter, the ice surface or the whole is melted, so that it does not substantially adhere to the filter. As a result, formation of adhering ice on the filter 3 is effectively prevented, and clogging of the filter and an increase in transfer resistance are also effectively prevented.

On the other hand, in order to sufficiently exhibit such an effect, it is preferable to always heat the filter during the solid-liquid separation as described above. However, if necessary, for example, the supply load of the supply pump may be reduced. Only when the value exceeds a predetermined value (it can be determined that the adhesion of ice to the filter has progressed to some extent), the fan 5C is operated to heat the filter and to melt the ice attached to the filter 3. Can also.

The heater 5D in the illustrated example is a belt type heater through which a heating wire passes, and is used by being wound around the outer peripheral surface of the air duct 5B. A heating pipe through which a heating medium (hot water or steam) passes may be attached to the inside or outside of the pipe line 5B. Also, in the case of a belt-type heater, it may be provided inside the air duct 5B.

In the illustrated example, the blower duct 5B is communicated with a portion of the cylindrical retaining wall corresponding to the filter start end. However, the tubular retaining wall 5A is connected to another portion such as the filter end or the center. You may send warm air inside.

Further, the tubular retaining wall 5A in the illustrated example surrounds the entire outer peripheral surface of the filter 3. For example, the tubular retaining wall 5A surrounds only the filter start end, only the filter end, or only the filter center. Walls can also be provided. The tubular retaining wall 5A in the illustrated example is one in which the filter start end and the filter end are open, but either one is closed, or both are closed and the cylindrical retaining wall is closed. It is also possible to provide an exhaust port at an appropriate position.

<Second Embodiment> Next, FIG. 2 shows an ice slurry solid-liquid separator 20 according to a first embodiment. In the present solid-liquid separation device example, instead of the contact heating means in the first embodiment, the outer peripheral surface of the filter 3 is surrounded at a predetermined interval with respect to the outer surface of the filter 3.
A heating tubular retaining wall 31 in which a heater 32 is embedded is provided. These constitute the non-contact heating means 30.

The heating cylindrical retaining wall 31 in the illustrated example is attached to the outer surface of the starting end of the residual ice transfer pipe 4, and is configured to surround the entire outer peripheral surface of the filter terminal side (half). The heater 32 is passed through substantially the entire inside. Of course, this heated tubular retaining wall 31
Is a specific part of the filter 3, for example, the filter 3
May be configured so as to surround only the entire outer peripheral surface of the starting end side portion or the central portion. In addition, this heater 32
It is not necessary to pass through the entire heating retaining wall 31, and only a part of the heating retaining wall 31 may be passed. As in the first embodiment, a heating tube through which a heating wire or a heating medium (hot water or steam) that generates heat by electric power can be used as the heater 32.

In the case of this embodiment, the heat of the heater 32 is radiated toward at least the filter 3 via the retaining wall material, and this radiant heat is passed between the inner surface of the heated cylindrical retaining wall 31 and the outer surface of the filter 3. 3, the filter 3 is warmed. Therefore, unlike the first embodiment, the filter 3 is heated in a non-contact manner in the second embodiment. Since the solid-liquid separation method including the heating timing and other device configurations are the same as those in the first embodiment, the same reference numerals are used and the description is omitted.

<Third Embodiment> As shown in FIG. 3, heaters 40 and 40 are wound around the outer peripheral surfaces of the filter ends in the remaining ice transfer line 4 and the ice slurry transfer line 2, respectively. The heat from the heaters 40, 40 may be transferred to the filter 3 via the transfer lines 4, 2. In this case, it is needless to say that the filter 3 and the transfer conduits 4 and 2 are preferably formed of a metal material having good heat conductivity. A heater may be provided in only one of the remaining ice transfer line 4 and the ice slurry transfer line 2.

<Fourth Embodiment> As shown in FIG. 4, heaters 50 and 5 are provided on the outer peripheral surfaces of the starting end and the end of the filter 3.
Alternatively, the heat from the heaters 50 may be directly transmitted to the filter 3.
In this case, the filter 3 is preferably formed of a metal material or the like having good heat conductivity. A heater may be provided only at one of the starting end and the end of the filter 3.

<Fifth Embodiment> In the second embodiment shown in FIG. 2, when the filter is made of metal, instead of the heater 32, an electric wire that does not generate heat is passed and the filter 3 is included by supplying power to this electric wire. Generate a magnetic field in the part,
An induction heating method in which the filter 3 generates heat without being in contact with the filter 3 can also be used. In this case, instead of directly melting the attached ice, the filter 3 can be heated by induction heating to indirectly melt the ice attached to the filter 3 or the ice in contact with the filter 3.

<Others> On the other hand, in the above example, heat is supplied from the outside of the filter 3 or the transfer pipes 4 and 2. However, in the present invention, a heating means may be provided inside or inside the wall of the filter 3 or the transfer conduits 4 and 2 (not shown).

Further, other means for preventing ice adhesion in the present invention include a filter surface (preferably, an inner surface and an inner surface of a through-hole,
More preferably, the entire surface is coated with a fluorine-based resin or other water-repellent substance, the filter is formed of a material such as PVC resin to which ice does not easily adhere, or the filter (preferably the inner surface and the inner surface of the through-hole, The method includes applying an anti-adhesion agent such as a surfactant to the entire surface (preferably the entire surface) and polishing the filter surface (preferably the inner surface and the inner surface of the through hole, more preferably the entire surface).

[0030]

As described above, according to the present invention, clogging of a filter can be prevented when a liquid component in an ice slurry containing ice as a solid content is separated through a filter. .

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view schematically showing a solid-liquid separation device according to a first embodiment of the present invention.

FIG. 2 is a longitudinal sectional view schematically showing a solid-liquid separation device according to a second embodiment of the present invention.

FIG. 3 is a longitudinal sectional view schematically showing a solid-liquid separation device according to a third embodiment of the present invention.

FIG. 4 is a longitudinal sectional view schematically showing a solid-liquid separation device according to a fourth embodiment of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Solid-liquid separation apparatus, 2 ... Ice slurry transfer pipe, 3 ... Cylindrical filter, 4 ... Residual ice transfer path, 5 ... Ice adhesion prevention means, 1
0: ice slurry, 12: ice content.

Continuation of the front page (71) Applicant 390005407 Asahi Glass Engineering Co., Ltd. 2-6-6 Nakase, Mihama-ku, Chiba City, Chiba Prefecture (72) Inventor Shun Miyata 7033-182, New Japan Air Conditioning Co., Ltd., in Nihon Air Conditioning Co., Ltd. (72) Inventor Hirotaka Terai 7033-182, New Japan Air Conditioning Co., Ltd., in Niigata Air Conditioning Co., Ltd., 7073-182, Japan Nippon Air Conditioning Co., Ltd. (72) Inventor Naoki Kuroda, 7033-182 New in Nihon Air Conditioning Co., Ltd., Miyano, Chino City, Nagano Prefecture, Japan (72) Inventor Yoshio Sugita 5-19-18 Kokumo, Kofu City, Yamanashi Prefecture F-Term in YEOL Electronics Co., Ltd. 4D064 AA01 AA40 BA03 BA14 BA34 DB01 DB02 DB03

Claims (3)

[Claims] 1. An ice slurry solid-liquid separation device for separating a liquid component in an ice slurry containing ice as a solid component through a filter, wherein an ice adhesion preventing means for preventing ice from adhering to the filter is provided. An apparatus for solid-liquid separation of an ice slurry. 2. The apparatus for solid-liquid separation of ice slurry according to claim 1, wherein a heating means for directly or indirectly heating ice attached to the filter or ice in contact with the filter is provided as said ice adhesion preventing means. 3. The apparatus for solid-liquid separation of ice slurry according to claim 1, wherein said filter is provided with a water-repellent coat as said means for preventing ice adhesion.