System and Method for Preserving Red Meat by Plasma Active Water (PAW) Vacuum Packaging

Abstract

A system for preserving red meat by plasma active water (PAW) vacuum packaging includes a solution mixing tank, a plasma treatment chamber, an atomization spray module, a conveyor bell, a water circulation module, and a vacuum packaging module. The solution mixing tank, the plasma treatment chamber, the atomization spray module, and the water circulation module are sequentially connected through pipes. The atomization sprav module is configured to spray PAW onto the red meat on the conveyor belt, and the vacuum packaging module is configured to vacuum-package the red meat. Utilizing PAW improves the antibacterial ability of vacuum packaging while enhancing the color stability of red meat, greatly extending the shelf life of red meat, thereby preserving red meat in a green and economical way.

Claims

1. A system for preserving red meat by plasma active water (PAW) vacuum packaging, comprising a solution mixing tank, a plasma treatment chamber, an atomization spray module, a conveyor belt, a water circulation module, and a vacuum packaging module; wherein the solution mixing tank, the plasma treatment chamber, the atomization spray module, and the water circulation module are sequentially connected through pipes; and wherein the atomization spray module is configured to spray red meat on the conveyor belt, and then the vacuum packaging module is configured to vacuum-package the red meat.

2. The system for preserving red meat by PAW vacuum packaging according to claim 1, wherein the plasma treatment chamber, configured to prepare PAW, comprises a surface dielectric barrier discharge excitation device at the top and a stirring device at the bottom.

3. The system for preserving red meat by PAW vacuum packaging according to claim 2, the plasma treatment chamber further comprises a plasma treatment tank, the stirring device at the bottom of the plasma treatment tank, and the surface dielectric barrier discharge excitation device at the top of the plasma treatment tank, a transformer connected to the surface dielectric barrier discharge excitation device; and a porous mesh fiber layer arranged below the surface dielectric barrier discharge excitation device, wherein the porous mesh fiber layer is configured to make the generated plasma uniformly contact a base solution; and wherein the stirring device at the bottom of the plasma treatment tank is configured to stir the base solution such that upper and lower layers of the base solution constantly exchange positions with each other.

4. The system for preserving red meat by PAW vacuum packaging according to claim 3, wherein the surface dielectric barrier discharge excitation device comprises: a discharge electrode, a ground electrode, and a quartz dielectric plate; wherein the quartz dielectric plate is placed between the discharge electrode and the ground electrode to generate surface dielectric barrier discharge plasma.

5. The system for preserving red meat by PAW vacuum packaging according to claim 4, characterized in that: the ground electrode is a round block with a diameter of 3.0 mm.

6. The system for preserving red meat by PAW vacuum packaging according to claim 1, further comprising a pressure regulator interposed among the pipes to control flow and velocity of liquid.

7. A method for preserving red meat by PAW vacuum packaging using the system according to claim 1, comprising: preparing PAW in the plasma treatment chamber; cutting the red meat; spraying PAW uniformly on the surface of the red meat, with the weight ratio of the red meat to PAW at (60+10):1; and immediately vacuum-packaging the red meat sprayed with PAW. and then refrigerating or freezing the red meat for preservation.

8. The method for preserving red meat by PAW vacuum packaging according to claim 7, wherein using the plasma treatment chamber to prepare PAW comprises: preparing 0.02-0.06 mol/L sodium pyrophosphate solution as a base solution; and adjusting the treatment time of the plasma treatment chamber according to the treatment area of the plasma treatment chamber, the volume of the base solution, and the surface area, to obtain PAW having a pH greater than or equal to ≥6.0, a NO.sup.2− concentration of 100 ppm, and H.sub.2O.sub.2 concentration of no more than 2 mmol/L.

9. The method for preserving red meat by PAW vacuum packaging according to claim 8, wherein the plasma treatment chamber uses a voltage of 50-60 V and a frequency of 10 kHz, and wherein the plasma treatment chamber directly utilizes air as a gas source for plasma excitation, adopting an indirect plasma treatment method.

10. The method for preserving red meat by PAW vacuum packaging according to claim 7, wherein the PAW may be freshly prepared, stored at room temperature for at most 48 h, or refrigerated at 4° C. for at most 2 weeks.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0032] FIG. 1 shows the structure of the system for preserving red meat by PAW vacuum packaging in an example of the present invention;

[0033] FIG. 2 shows the structure of the plasma treatment chamber in an example of the present invention;

[0034] FIG. 3 is a flowchart of the method for preserving red meat by PAW vacuum packaging in an example of the present invention; and

[0035] FIG. 4 shows the fresh-keeping effects of PAW on red meat in an example of the present invention for comparison.

DETAILED DESCRIPTION

[0036] The present invention will be further described below in detail with reference to specific embodiments, but the embodiments of the present invention are not limited thereto.

[0037] As shown in FIG. 1, the system for preserving red meat by PAW vacuum packaging comprises a solution mixing tank 1, a plasma treatment chamber 2, an atomization spray module, a conveyor belt 5, a water circulation module 6, and a vacuum packaging module 7; wherein the solution mixing tank, the plasma treatment chamber, the atomization spray module and the water circulation module are sequentially connected through pipes; a pressure regulator 16 is interposed among the pipes to control the flow and velocity of the liquid; and the red meat 4 on the conveyor belt is sprayed by the atomization spray module, and then vacuum-packaged by the vacuum packaging module.

[0038] The plasma treatment chamber, used to prepare PAW 15, is provided with a surface dielectric barrier discharge excitation device at the top and a stirring device at the bottom. Specifically, as shown in FIG. 2, the plasma treatment chamber comprises a transformer 3, a plasma treatment tank 9, a stirring device 10 at the bottom, and a surface dielectric barrier discharge excitation device at the top (the surface dielectric barrier discharge excitation device comprises a discharge electrode 11, a ground electrode 12 and a quartz dielectric plate 13, wherein a 1.0 mm thick quartz dielectric plate is placed between the discharge electrode and the ground electrode to generate surface dielectric barrier discharge plasma, and the ground electrode is a round block with a diameter of 3.0 mm). The transformer, connected with the surface dielectric barrier discharge excitation device of the plasma treatment chamber, is used for inputting an alternating current with a voltage of 220 V and a frequency of 50 Hz, and for outputting an alternating current with a voltage of 0-100 V and a frequency of 0.5-2.0 kHz, with the outputted current used for excitation to generate plasma. The present invention proposes to use an alternating current with a frequency of 10 kHz and a voltage of 50-60 V, and directly use air as the gas source for plasma excitation. The porous mesh fiber layer 14, arranged below the surface dielectric barrier discharge excitation device, makes the generated plasma uniformly contact the base solution. Besides, the stirring device at the bottom is used to stir the base solution, so that the upper and lower layers of the base solution constantly exchange positions with each other, ensuring the full contact of the base solution with the plasma, thereby improving the efficiency of preparing PAW.

[0039] The solution mixing tank is used to prepare or store the base solution of PAW. In this example, the base solution is a sodium pyrophosphate solution 8.

[0040] The atomization spray module comprises a pressure regulator 16 and an atomization spray device 17.

[0041] The water circulation module comprises an active water collector 18 and a vacuum pump 19.

[0042] In this example, the control process of the system for preserving red meat by PAW vacuum packaging is as follows: A sodium pyrophosphate solution is prepared in the solution mixing tank that communicates with the plasma treatment chamber; the prepared sodium pyrophosphate solution continuously flows into the plasma treatment chamber through a pipe, which is provided with a pressure regulator to control the flow of the solution; with the solution mixing tank and the plasma treatment chamber in a high position, and the atomization spray module and the water circulation module in a low position, the porous mesh fiber layer in the plasma treatment chamber makes the plasma uniformly distributed, the treated sodium pyrophosphate solution (PAW) is introduced into the atomization spray module and sprayed onto the red meat on the conveyor belt (the appropriate transmission speed of the conveyor belt is set according to the weight ratio of red meat to PAW of (60±10):1), the pressure regulator controls the flow, and the excess PAW reenters the atomization spray module through the water circulation module; the sprayed red meat is transferred to the vacuum packaging module for vacuum packaging; finally, the packaged red meat is refrigerated or frozen.

[0043] As shown in FIG. 3, a method for preserving red meat by PAW vacuum packaging comprises the following steps:

[0044] S1. using the plasma treatment chamber to prepare PAW, specifically as follows:

[0045] first preparing 0.02-0.06 mol/L sodium pyrophosphate solution as a base solution; and

[0046] then appropriately adjusting the treatment time according to the treatment area of the plasma treatment chamber (i.e. the area of the plasma region formed by the dielectric barrier discharge excitation device at the top of the plasma treatment chamber), the volume of the base solution to be treated, and the surface area, to finally obtain PAW (pH≤6.0, NO.sup.2− concentration of about 100 ppm, and H.sub.2O.sub.2 concentration of no more than 2 mmol/L);

[0047] the plasma treatment chamber is a surface dielectric barrier discharge plasma treatment chamber with a voltage of 50-60 V and a frequency of 10 kHz, and directly utilizes air as a gas source for plasma excitation, adopting an indirect plasma treatment method;

[0048] S2. cutting the red meat;

[0049] red meat includes hot fresh meat, cold fresh meat, frozen thawed meat and minced meat of red meat; the hot fresh meat needs to be treated with PAW after acid discharge, while the cold fresh meat, frozen thawed meat and minced meat can be directly treated with PAW;

[0050] S3. spraying PAW uniformly on the surface of the red meat, with the weight ratio of the red meat to PAW at (60±10):1;

[0051] PAW may be freshly prepared, stored at room temperature for at most 48 h, or refrigerated at 4° C. for at most 2 weeks, which do not affect their final color retention effect on red meat;

[0052] S4. immediately vacuum-packaging the red meat sprayed with PAW, and then refrigerating (1° C. to 4° C.) or freezing (−20° C. to −18° C.) the red meat for preservation.

[0053] The mechanism of the present invention is as follows: PAW contains NO.sup.2− and NO.sup.3−, both of which are effective color retention agents for red meat; moreover, PAW contains a small amount of hydrogen peroxide and other antibacterial components, which not only keep the color of red meat but also enhance the antibacterial ability of vacuum packaging, achieving color retention and antibacterial effect on red meat, thus greatly extending the shelf life.

[0054] As shown in FIG. 2, the method for preserving red meat by PAW vacuum packaging in this example is specifically implemented as follows:

[0055] 0.02 mol/L sodium pyrophosphate solution was prepared, and 1000 mL of the solution was introduced into the plasma treatment chamber; plasma was generated by surface dielectric barrier discharge excitation (voltage 60 V, frequency 10 kHz), and the introduced sodium pyrophosphate solution was indirectly treated for 30 min to finally obtain PAW (pH=9.11, NO.sup.2−95.30 ppm, NO.sup.3−239.21 ppm, and H.sub.2O.sub.2 0.544 mmol/L) to meet the requirements of use.

[0056] The area of the plasma region formed by the dielectric barrier discharge excitation device at the top of the plasma treatment chamber was 40 cm.sup.2, and the distance between the ground electrode and the surface of the liquid to be treated was 5 cm.

[0057] Twenty strips of untreated longissimus dorsi beef were purchased from the slaughterhouse and cut into 1 cm thick slices with a meat cutter; PAW was introduced into the atomization spray module and uniformly sprayed onto the surface of the beef on the conveyor belt.

[0058] The unsprayed PAW was introduced into an active water collector, and then transported back to the atomization spray module by a vacuum pump.

[0059] The beef sprayed with PAW entered the vacuum packaging module, and then the vacuum-packaged beef was refrigerated at 4° C.

[0060] At the same time, the beef that was only vacuum-packaged was prepared and refrigerated at 4° C. After 72 h, the color of the beef was inspected, with the results shown in FIG. 4. It was found that the redness (a* value) of the beef that was vacuum-packaged after PAW treatment was higher, while the redness (a* value) of the only vacuum-packaged beef was lower. This indicated that the present invention could effectively improve the color stability of vacuum-packaged red meat.

[0061] The above examples are preferred embodiments of the present invention, but the embodiments of the present invention are not limited thereto, and any other alterations, modifications, replacements, combinations and simplifications made without departing from the spirit and principle of the present invention shall all be equivalent substitutions and included in the scope of protection of the present invention.