WO2021261983A1

WO2021261983A1 - System for evaporating defrosting water from a cooling unit by heat exchange between the air intended to cool the condenser and said defrosting water

Info

Publication number: WO2021261983A1
Application number: PCT/MA2021/000006
Authority: WO
Inventors: Ezzitouni KHIYARI
Original assignee: Khiyari Ezzitouni
Priority date: 2021-02-08
Filing date: 2021-05-17
Publication date: 2021-12-30
Also published as: MA52399A1; MA52399B1

Abstract

Disclosed are a device and a physical technical method for disposing of the water from the forced-air evaporator of a cooling unit and for using the energy thereof to reduce the consumption of electrical energy and to increase the profitability of cooling apparatus. Said device uses apparatus that is easy to install and manufacture and is efficient in solving the problems of leakage from the evaporation tube, referred to as the serpentine coil, of water discharged from the evaporator during the defrosting process.

Description

Defrost water evaporation system of a cooling unit by heat exchange between the air intended to cool the condenser and said defrost water

Technical field of the invention

The invention relates to defrost water evaporation systems for commercial refrigeration units with compact units.

The technical problem addressed by the invention

It is known that in commercial refrigeration devices operating with compact units, the coil leaving the compressor is used at high pressure and high temperature to evaporate the water from the forced air evaporator during the defrost process, and in this coil, gas leaks often occur.

In this case of a leak, the appliance loses the total amount of gas it contains and shuts down permanently, and there are sensitive appliances such as freezers, and the appliance may suddenly stop in the absence of the user of the device, which causes material loss for the user, and also a lot of losses and technical malfunctions in the device in the absence of a protection device with a safety to stop the device when a gas leak occurs. This is because the gas leak can cause the compressor to absorb water in the tank and contaminate the circuit also with air and humidity, and the compressor will continue to operate without gas until it is destroyed, not to mention the negative impact of the gases used in refrigeration equipment on the environment, which causes global warming. State of the prior art

Document EP 2 432 350 B1 discloses a process for evaporating the water from defrosting, but while keeping the coil.

Advantages and Disclosure of the Invention The solution consists in the elimination of the coil, and the evaporation of the defrost water by heat exchange.

It is a physical technical device and process for evaporating the water from the evaporator during the defrosting process by using the air intended to cool the forced-air condenser by passing through an absorption room ( 2) after passing through the air filter (20), to filter it from dust (see drawing n ° 4).

The advantage of this solution is to eliminate the problems of gas leakage in the coil, and to improve the efficiency of the refrigeration unit while saving its energy. An exchange of heat between air and water allows the air to lose an amount of heat which helps in the process of water evaporation. In order for water to evaporate at a temperature of 20 ° C, the latent temperature of its evaporation is 2454 kilojoules / kg, and this amount is taken from the air going to the condenser. In this process, we use the energy of the water to cool the air going to the condenser, in order to reduce the condensing temperature of the gas and save on the consumption of energy supplying the compressor. Note that increasing the gas condensing temperature by one Kelvin leads to an increase in compressor consumption by 1 to 3% and a decrease in the performance factor by 8%. The heat exchange between the air and the water coming down from the evaporator causes the air to lose a quantity of heat to be used for the drop in the gas condensing temperature and thus to save electrical energy.

To effectively ensure this exchange, the solution is to manufacture an absorption part adapted to the dimensions of the condenser, with a frame made of anti-corrosion material according to the measurements of the condenser. It is placed between the condenser and the dust air filter. It contains in its core sponge rolls capable of absorbing a quantity of water coming from the evaporator and allowing the air going to the condenser to pass easily after having been filtered from the dust by a filter controlled by a thermostat. or a pressure switch to alert the user to the need for filter maintenance. A water tank (4) is placed under the frame which includes the sponge made as shown in drawing n ° 1 to receive the drops of water coming from the sponge when the latter is saturated with water, and to let the air pass underneath to evaporate the water it contains in a natural way.

The absorption piece (drawing 1) consists of a frame made of corrosion-resistant metal or plastic, which has inside sponge rollers capable of absorbing water that comes directly from the evaporator into the tank (18) shown in drawing n ° 4, which descends from the tube (6) descending from the evaporator, which is sucked by the pump (10) from the collection tank (4.1) to be pumped in the direction of at least a water sprayer (1) on the surface of the absorption piece on the upper side in the form of a funnel (8) to fall inside the piece and be absorbed by the sponges. Once the sponge is saturated, drops of water fall into the tray (4) at the bottom of the room. Air passes under it to aid in the process of evaporating the water, and the process is repeated, supplying the pump with water coming down from the evaporator.

An electrical resistance (15) is placed in the collection tank (4.1) to evaporate the water in the event of a pump malfunction or the presence of water with abundance in said tank. The electric resistance works by an automatic system when the water level rises in the collection tank (4.1).

Embodiments

For mounting the pump, two embodiments are possible. The pump can work in parallel (drawing 2) with the compressor, so it will only work when the compressor is running, and operates continuously using its automatic system in contact with water. .

The pump can also be installed with independent operation of the compressor, regulated by its automatic on / off system, said system is mounted in series with the suction tube of the pump (drawing 3).

In this preferred embodiment, the pump operates independently of the compressor, so at the start-up phase of the compressor, it finds the wet sponge with water already absorbed, to supply the condenser with air. cold. Description of the drawings

Drawing 1 shows the absorption piece designed to receive the water coming down from the evaporator, the pump and the tank to evaporate the water by heat exchange between it and the air and the electric resistance added to the system

1 - Water sprayer 2- Water absorption part in corrosion-resistant metal or plastic

3- Sponge

4- Water tank

4.1 - Water collection tank

5- Air passage 6- Defrost water tube

7- Empty part under the tank 8- Upper part of the absorption part in the form of a funnel

9- The water in tank 4

10- Water pump

11 - Pump delivery pipe 12- Air passage above the tank

13- Pump suction tube

14- Connecting water tube between the two tanks 4 and 4.1

15- Electrical resistance

16- Water level control system in the tank

Drawing 2 shows the electrical control circuit of the system used to alert the user to the need for maintenance of the air filter and the water evaporation device, the pump works in parallel with the compressor

- S1 on / off switch - H indicator light under voltage

- P defrost clock

- B1 regulation thermostat

- M1 compressor motorcycle

- KA1 Delayed time delay relay at rest: to stop the motor-fan after the compressor to dry the sponge and cool the compressor

- M2 condenser fan motor

- B2 Mechanism for regulating the operation of the water pump

- M3 Water pump

- H2 Pump on indicator light - M4 evaporator fan motorbike

- B3 gas temperature control thermostat at the condenser outlet for maintenance of the condenser filter

- K2 alarm system power relay for filter maintenance

- S2 alarm system stop switch - K alarm system

- H3 warning light for air filter maintenance

- B4 mechanism for regulating the operation of the defrost water vaporization resistance

- R Water vaporization resistance

- H4 Resistor on indicator light.

Figure 3 shows the electrical control circuit of the air filter maintenance warning device, the water evaporation device and the operation of the electric resistance (15), the pump operating independently of the compressor. '' permanently with its automatic regulation system, which makes it work once the water reaches the pump on the suction side:

- S1 on / off switch

- H indicator light under voltage

- P defrost clock

- B1 regulation thermostat

- M1 compressor motorcycle

- KA1 Delayed time delay relay at rest

- M2 condenser fan motor

- B2 Mechanism for regulating the operation of the water pump

- M3 Water pump

- H2 Pump on indicator light

- M4 evaporator fan motor

- K2 alarm system power relay for filter maintenance

- S2 alarm system stop switch

- K alarm system

- H3 warning light for air filter maintenance - B4 mechanism for regulating the operation of the defrost water vaporization resistance

- R Water vaporization resistance

- H4 Resistor on indicator light.

Drawing 4 shows a cooling device with the technology of the invention

I - Water sprayer

2- Water absorption piece in water resistant metal or plastic

3- Sponge

4- Water tank

4.1 - Water collection tank

5- Air passage

6- Defrost water tube

8- Upper part of the room in the form of a funnel

9- The water in the tank

10- Water pump

I I - Pump discharge pipe

13- Pump suction tube

14- Connecting tube between the two tanks

15- Electrical resistance

16- Water level control system in the tank

17- Thermostat for controlling the gas temperature at the condenser outlet and signaling the saturation of the filter with dust

18- Evaporator defrost water tank

19- Forced air evaporator

20- Condenser air filter 21 - Forced air condenser

Claims

1. Defrost water evaporation system of a cooling unit by heat exchange between the air intended to cool the condenser and said defrost water, without coil, comprising a forced air evaporator (19), a forced air condenser (21), a compressor, a defrost water tank (18) below the evaporator (19), said defrost water evaporation system is characterized in that it comprises:

- at least one water sprayer (1)

-a water absorption part (2) which is placed at the air inlet level of the condenser (21)

- A tank (4) for collecting the water flowing from said absorption part, located below said part

- a water collection tank (4.1) which collects the water from the tank 18 and that of the tank 4, said collection tank (4.1) contains an electrical resistance (15) - a water pump (10) which sucks the water 'water from the collection tank (4.1) and pump it to said at least water sprayer (1)

-a defrost tube (6) connecting said defrost water collection tank (18) and tank 4.1.

at least one air filter (20) for filtering the air intended to cool the condenser and to pass through said absorption part.

-a thermostat (17) for controlling the temperature of the gas at the outlet of the condenser (21) for signaling the saturation of the air filter (20) by dust.

- a water level control system (16) in the tank (4.1).

2. Defrost water evaporation system according to claim 1 characterized in that the absorption part (2) is composed of a frame, said frame having an upper part in the form of a funnel (8), and contains inside wrapped sponge rolls (3) capable of absorbing a quantity of water and allowing air to pass underneath.

3. Defrost water evaporation system according to claim 2, characterized in that the absorption part (2) has dimensions adapted to the condenser (21).

4. Defrost water evaporation system according to claim 3 characterized in that the pump operates in parallel with the compressor.

5. Defrost water evaporation system according to claim 3 characterized in that the pump (10) operates independently of the compressor, and operates continuously with its control system.

6. Cooling unit comprising a defrost water evaporation system by heat exchange between the air intended to cool the condenser and said defrost water, without coil, comprising a forced air evaporator (19), a condenser forced air (21), a compressor, a defrost water tank (18) below the evaporator (19), said defrost water evaporation system is characterized in that it comprises:

- at least one water sprayer (1)

-a water absorption part (2) which is placed at the air inlet level of the condenser

(21)

- A tank (4) for collecting the water flowing from said absorption part (2), located below said part

- a collection tank (4.1) which collects the water from the tank 18 and that from the tank 4, said collection tank (4.1) contains an electrical resistance (15) - a water pump (10) which sucks water from the tank (4.1) and pumps it to said at least water sprayer (1)

-a defrost tube (6) connecting said defrost water collection tank (18) and tank 4.1. at least one air filter (20) for filtering the air intended to cool the condenser and to pass through said frame.

- a water level control system (16) in the tank (4.1).