CN213119726U - Energy-saving chemical cooler for circulating refrigeration - Google Patents

Abstract

The utility model discloses a circulating refrigeration's energy-conserving chemical industry cooler, including inlet tube and cold water storage cistern, the suction pump in inlet tube one end mouth of pipe and the cold water storage cistern is connected, is equipped with the condensate in the cold water storage cistern, and inlet tube other end mouth of pipe passes through flange and condenser pipe fixed connection, and the free mouth of pipe of condenser pipe passes through flange fixed connection outlet pipe, and another mouth of pipe slope of outlet tube, the outlet tube mouth of pipe sets up in the buckled plate top, and the outlet tube is parallel with the buckled plate, and the outlet tube contacts with the buckled plate. By adding the turbulence teeth, the condensate accelerates the heat dissipation in the turbulence, and the cooling efficiency is increased; the corrugated plate is added, so that condensate flows in a non-directional manner to form turbulent flow, the corrugated plate has direct air exchange with the outside to accelerate heat dissipation, and the corrugated plate guides the flow to enable the condensate to return to the cold water tank; through adding the cold wind nest of tubes, the cold wind pipe of cold wind nest of tubes equals with the buckled plate distance, can stably blow to the condensate, prevents that liquid from splashing.

Description

Energy-saving chemical cooler for circulating refrigeration

Technical Field

The utility model relates to a cooling device field specifically is a circulation refrigerated energy-conserving chemical industry cooler.

Background

The cooler makes one kind of indirect heating equipment, a be used for cooling fluid, water or air remove the heat for the coolant usually, take away a large amount of heats in the low temperature water or the air flow, for more abundant utilization water resource, water economy, mainly use circulating water cooler among the prior art, make the water that contains the heat put into use once more after cooling treatment, circulating cooler among the prior art mainly relies on the cooler to make the coolant cooling that contains the heat, it is more to consume the energy, be not conform to energy-concerving and environment-protective requirement, need more structure that adds energy-conservation be used for improving cooling efficiency, reduce the use of cooler, reach energy-conserving purpose, the condensate that will contain a large amount of heats partly through various steps, then the cooler is more convenient to the cooling of condensate. Therefore, the utility model provides a circulating refrigeration's energy-conserving chemical industry cooler.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a circulating cooling's energy-conserving chemical industry cooler to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

the utility model provides a cryogenic energy-conserving chemical industry cooler circulates, includes inlet tube and cold water storage cistern, inlet tube one end mouth of pipe is connected with the suction pump in the cold water storage cistern, is equipped with the condensate in the cold water storage cistern, and inlet tube other end mouth of pipe passes through flange and condenser pipe fixed connection, and the condenser pipe sets up threely, through flange joint between the condenser pipe, and the free mouth of pipe of last condenser pipe passes through flange fixed connection outlet pipe, and another mouth of pipe slope of outlet tube, the outlet tube mouth of pipe sets up in the buckled plate top, and the outlet tube is parallel with the buckled plate, and the outlet tube contacts with the buckled plate.

Preferably, the buckled plate is the hang plate, and the buckled plate top sets up the ripple, and the one end that the buckled plate is down is located the cold water tank.

Preferably, the buckled plate sets up in the shell, and the shell is trapezoidal, and the shell top sets up the thermantidote, and the thermantidote below sets up the baffle, and the thermantidote below sets up the cold wind nest of tubes, and the buckled plate is located the bottom surface of shell, shell below fixed mounting support.

Preferably, the cold blast nest of tubes sets up the triplex row altogether, and the distance between the cold blast pipe mouth of each row and the buckled plate equals, and the baffle is passed to cold blast nest of tubes top.

Preferably, the turbulence teeth are fixedly arranged in the condensation pipe, the turbulence teeth are a group of protrusions which are arranged at equal angles, and the protrusions of the turbulence teeth are parallel to the condensation pipe.

Compared with the prior art, the beneficial effects of the utility model are that:

1. by adding the turbulence teeth, the condensate absorbing heat in the condensation pipe accelerates the heat dissipation in the turbulent flow, so that the secondary cooling efficiency of the condensate is increased;

2. by adding the corrugated plate, condensate passing through the condenser pipe flows over the corrugated plate, the corrugation on the corrugated plate enables the condensate to flow in a non-directional manner, the corrugated plate is communicated with the outside, the condensate on the corrugated plate is cooled in an accelerated manner, the corrugated plate is inclined downwards, the lower end of the corrugated plate is positioned in the cold water tank, and the cooled condensate flows into the cold water tank along the corrugated plate;

3. through adding the cold wind nest of tubes, the wind that the thermantidote blew off blows the condensate to on the buckled plate along the cold wind nest of tubes, and the thermantidote and the buckled plate distance of cold wind nest of tubes equal, then can be stable blow to the condensate, prevent that liquid from splashing, and the thermantidote mouth of pipe is perpendicular downwards, blows the condensate downwards along buckled plate incline direction.

Drawings

FIG. 1 is a schematic structural view of the utility model;

FIG. 2 is a cross-sectional view of a condenser tube;

FIG. 3 is a side view of the housing and bracket;

fig. 4 is a front view of the housing.

In the figure: the cooling device comprises an inlet pipe 1, a condenser pipe 2, an outlet pipe 3, a cold water tank 4, a support 5, a cooling fan 6, a cold water pipe group 7, a corrugated plate 8, a shell 9 and disorder teeth 10.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below. The embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative work, all belong to the protection scope of the present invention.

Referring to fig. 1 to 4, the present invention provides a technical solution:

the utility model provides a circulating cooling's energy-conserving chemical industry cooler, including inflow pipe 1 and cold water storage cistern 4, the suction pump in inflow pipe 1 one end mouth of pipe and the cold water storage cistern 4 is connected, the condensate is equipped with in the cold water storage cistern 4, the suction pump is extracted coolant liquid from cold water storage cistern 4 and is got into inflow pipe 1, 1 other end mouth of pipe of inflow pipe passes through flange and 2 fixed connection of condenser pipe, condenser pipe 2 sets up threely, also can increase or reduce the quantity of condenser pipe 2 as required, through flange joint between the condenser pipe 2, the free mouth of pipe of last condenser pipe 2 passes through flange fixed connection outflow pipe 3, 3 another mouth of pipe slopes of outflow pipe, 3 mouths of pipe of outflow pipe set up in 8 tops of buckled plate, 3 lower extreme mouths of outflow pipe and 8 parallel just laminating closely of buckled plate, guarantee from the condensate that flows out in the outflow pipe 3 along.

The corrugated plate 8 is an inclined plate, the corrugation is arranged above the corrugated plate 8, condensate flows over the corrugated plate 8 and is disordered by the corrugation to form turbulent flow, heat dissipation is accelerated, and the downward end of the corrugated plate 8 is positioned in the cold water tank 4;

the corrugated plate 8 is arranged in the shell 9, the shell 9 is trapezoidal, the cooling fan 6 is arranged above the shell 9, the baffle is arranged below the cooling fan 6, the cooling air pipe group 7 is arranged below the cooling fan 6, the corrugated plate 8 is positioned on the bottom surface of the shell 9, and the mounting bracket 9 is fixedly arranged below the shell 9;

the cold air pipe groups 7 are arranged in three rows in total, the distance between the pipe orifice of each row of cold air pipe and the corrugated plate 8 is equal, cold air blown to the corrugated plate 8 is uniform and stable, condensate is prevented from splashing, and the upper part of each cold air pipe group 7 penetrates through the baffle;

disordered tooth 10 of inside fixed mounting of condenser pipe 2, disordered tooth 10 is the arch of a set of equal angular arrangement, and the condensate that flows into condenser pipe 2 is disorderly with higher speed the heat dissipation, and the arch of disorderly tooth 10 is parallel with the condenser pipe.

The working principle is as follows: the utility model discloses the during operation is fixed condenser pipe 2 on needs refrigerated work piece, and condenser pipe 2 can increase or reduce quantity according to the cooling object, and in the condensate of starting the water pump in with cold water storage cistern 4 transported inflow pipe 1, the water pump belongs to prior art, does not give the repeated description here. Condensate flows into condenser pipe 2 from inlet pipe 1, the condensate flows into outlet pipe 3 from condenser pipe 2 after absorbing the heat on the work piece, set up out of disorder tooth 10 in the condenser pipe 2, the condensate forms the turbulent flow in condenser pipe 2, the heat of condensate gives off partly with higher speed, the mouth of pipe of outlet pipe 3 is on buckled plate 8, the condensate of outflow flows through from buckled plate 8, ripple on the buckled plate 8 makes the condensate non-directional flow, buckled plate 8 and external intercommunication, the condensate on the buckled plate 8 cools off with higher speed, 8 slopes of buckled plate are downward, and the lower extreme is located cold water storage cistern 4, the condensate after the cooling flows into cold water storage cistern 4 along buckled plate 8, wait to be extracted once more and carry out the cooling operation. When the condensate flows on buckled plate 8, buckled plate 8 sets up in shell 9, shell 9 top installation thermantidote 6, the wind that thermantidote 6 blew out blows the condensate on 8 buckled plates along cold wind nest of tubes 7, the thermantidote and 8 distances of buckled plate of cold wind nest of tubes 7 equal, then 6 can be stable of thermantidote are bloied to the condensate, the cold wind quick cooling that makes the thermal condensate of diffusion through the turbulent flow by 6 bleeds of thermantidote, also can prevent that the liquid from splashing, the thermantidote mouth of pipe is perpendicular downwards, blow the condensate downwards along buckled plate incline direction, the condensate that the cooling was accomplished gets back to in cold water tank 4 along 8 buckled plates, wait for being used by circulation. The shell 9 is fixed on the support 5, and the support 5 is according to cold water tank 4 adjustment position, guarantees that the lower extreme of buckled plate 8 is located cold water tank 4, makes the condensate can follow buckled plate 8 and get back to cold water tank 4.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a cryogenic energy-conserving chemical industry cooler of circulation, includes inlet tube (1) and cold water storage cistern (4), its characterized in that: the utility model discloses a solar water heater, including inlet pipe (1), condenser pipe (2), outlet pipe (3), another mouth of pipe slope of outlet pipe (3), outlet pipe (3) mouth of pipe sets up in buckled plate (8) top, outlet pipe (3) are parallel with buckled plate (8), outlet pipe (3) and buckled plate (8) contact.

2. The energy-saving chemical cooler of the circulation refrigeration as claimed in claim 1, wherein: the buckled plate (8) are inclined plates, the upper part of the buckled plate (8) is provided with ripples, and the downward end of the buckled plate (8) is positioned in the cold water tank (4).

3. The energy-saving chemical cooler of the circulation refrigeration as claimed in claim 1, wherein: buckled plate (8) set up in shell (9), and shell (9) are trapezoidal, and shell (9) top sets up thermantidote (6), and thermantidote (6) below sets up the baffle, and thermantidote (6) below sets up cold wind nest of tubes (7), and buckled plate (8) are located the bottom surface of shell (9), shell (9) below fixed mounting support (9).

4. The energy-saving chemical cooler of the circulation refrigeration as claimed in claim 3, characterized in that: the cold blast nest of tubes (7) set up the triplex row altogether, and the distance between the cold blast pipe mouth of each row and buckled plate (8) equals, and baffle is passed to cold blast nest of tubes (7) top.

5. The energy-saving chemical cooler of the circulation refrigeration as claimed in claim 1, wherein: disordered teeth (10) are fixedly arranged inside the condensation pipe (2), the disordered teeth (10) are a group of protrusions which are arranged at equal angles, and the protrusions of the disordered teeth (10) are parallel to the condensation pipe.

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