SE504172C2 - Device for the treatment of products with gas - Google Patents

Abstract

An apparatus for treatment of products with gas comprises a housing (1), a fan (4) for circulating treating gas in the housing, and a conveyor belt (2) having a foraminous product-carrying base (11) for moving the products through the housing, said conveyor belt following, along part of its length, a helical path in the housing. A duct (10) of subtantially rectangular cross section and of the same helical shape as the helical path of the conveyor belt (2) accommodates the conveyor belt in the helical path thereof, with the product-carrying base (11) positioned between the bottom and top of the duct. The bottom and top of the duct are closed, and the duct has a closure on its one side above and, on its other side, below the product-carrying base. Otherwise, the sides of the duct are gas-permeable. Means (6-8) are arranged for guiding the gas flow in the radial direction relative to a hollow cylinder formed of the duct, such that the gas flow passes through this via the foraminous product-carrying base of the conveyor belt in series with the gas-permeable parts of the sides of the duct adjacent to the product-carrying surface.

Description

504 172 10 15 20 25 30 35 comes over the strip stack and thus that undesirably large pressure differences will occur inside the housing.

A second way is to direct the flow radially through the belt stack, ie in the lateral direction of the conveyor belt. As a result, the pressure drop becomes relatively small and the products in the entire stack can be exposed to gas with one and the same property at the same time, however, the interaction between the gas and the products risks decreasing in relation to the case with vertical flow.

A third and normally undesirable way is to direct the flow so that it follows the conveyor belt in its longitudinal direction. Namely, in this case, the disadvantage of the first and the second way of directing the flow is combined. Thus, the properties of the gas gradually change as it passes through the strip stack and the interaction between the gas and the products becomes relatively weak. The object of the present invention is to provide a device of the type indicated in the introduction, which device has the advantages of the first way of directing the flow without giving rise to its disadvantages.

This object is achieved according to the invention with a device according to the following claim 1. Preferred embodiments of this device appear from the dependent claims.

Characteristic of the device according to the invention is thus that it uses a channel with a substantially rectangular cross-section and with the same helical shape as the helical path of the conveyor belt. This channel must have a closed bottom and a closed top.

These can be the same, ie the bottom of a channel turn can be the top of an underlying channel turn.

The channel further holds the conveyor belt in its helical path with the product-bearing base located between the bottom and the top. Finally, the duct has a closure on one side above and on the other side below the product-bearing base, while the sides of the duct are otherwise gas-permeable. 10 15 20 25 30 35 3 so4 172 As a result of the construction described above, gas introduced radially towards one side of the channel will pass in the radial direction through the gas permeable part of this side, then pass substantially vertically through the product-carrying base and finally pass in the radial direction out through the gas-permeable part of the other side of the duct.

Thus, the gas flow through each revolution of the belt stack can, for example, be connected in parallel with the gas flow through each other revolution of the belt stack, but is nevertheless directed vertically through the product-carrying base of the conveyor belt. Of course, the gas flow can be directed radially inwards or radially outwards through the hollow cylinder of the belt stack. Likewise, the gas flow can be directed vertically up through or down through the product-bearing base.

By arranging a plurality of gas flow channels, which open into predetermined areas or sections of the outside and / or inside of the strip stack, these sections can be connected in series and / or in parallel in any desired manner. In each duct, the gas can be further conditioned in the manner most suitable for treating the products within the associated sections.

In a preferred embodiment, the channel is provided by means of two conveyor belts, namely the product-conveying conveyor belt, which has a side portion which forms the lateral connection of the helical channel over the product-supporting base of the same conveyor belt, and a one interpolated with the product-conveying conveyor belt. conveyor belt, which thus follows a helical path with the same helical shape as the product-moving conveyor belt and which second conveyor belt forms the bottom, top and side connection of the duct below the product-supporting base. In this preferred embodiment, each conveyor belt further carries an overlying part of the other of the conveyor belt in the same manner as shown in, for example, US-A-5,031,751.

Alternatively, the bottom, top and sides of the channel can be stationary. In this case, the product-moving conveyor belt can have at least one gas-permeable side portion. If it has a single such portion, it should suitably be located on the same side of the channel as the closure of the channel below the product-carrying base of the conveyor belt.

However, it is also possible that the side connection of the channel over the product-bearing base forms part of the conveyor belt and is thus movable together with it.

The invention will be described in more detail in the following with reference to the accompanying drawings.

Fig. 1 is a perspective view showing a known type of device where the present invention is useful.

Fig. 2 is a schematic cross-sectional view showing the principle of the present invention.

Figs. 3-9 schematically show different embodiments of a helical channel, which is included in the device according to the invention.

Figs. 10-11 show different embodiments of controls for the gas flow in a device according to the present invention.

The devices described below preferably use air as treatment gas, but the invention is not limited thereto. Furthermore, they are primarily intended for freezing food, but this must not be regarded as limiting the invention either. Thus, the device can utilize such gases as, for example, carbon dioxide and nitrogen, it can treat products other than food and the treatment can involve other than freezing, eg cooling, heating, frying and drying.

The previously known device shown in Fig. 1 has a housing 1, to a part of its length following a helical path in which a conveyor belt 2 is arranged to thereby form a belt stack 3 in the form of a hollow cylinder. A fan 4 is arranged for circulation of air through the device, which air is given the desired temperature by means of a cooling coil 5.

Although the conveyor belt 2 is an endless one, its path outside the housing 1 is not shown in Fig. 1. In the schematic cross-sectional view in Fig. 2, the housing 1, the belt stack 3, the fan 4 and the cooling coil 5 are found. In Fig. 2 also show partitions 6, 7 and 8, which control the circulation of the air flow. More specifically, as indicated by arrows in Fig. 2, the air circulates radially through the strip of tape 3 from its outside to its inside and then returns to the outside via the fan 4 and the cooling coil 5.

According to the invention, the strip stack 3 is more precisely formed by a helical channel 10 with a substantially rectangular cross-section. This channel 10 has the same helical shape as the helical path of the conveyor belt 2 to accommodate the conveyor belt 2 in its helical path with a product-bearing base 11 of the conveyor belt 2 located between the bottom 12 and top 13 of the channel 10, which base 11 is preferably planar with a likewise essentially flat surface on which the products are to rest.

To illustrate various possible embodiments of the channel 10, a framed part 14 shown in Fig. 2 is illustrated on a larger scale in Figs. 3-9. The framed part comprises three superimposed turns of the channel 10. In Figs. 3-9, double lines represent a substantially gas-impermeable surface, while a gas-permeable surface is represented by a single line. The three turns of the channel 10 within the frame 14 are in Figs. 3-9 marked with dashed lines.

In the embodiment according to Fig. 3, the channel 10 is stationary with a gas-permeable bottom 12 and top 13. As can be seen from the figure, a bottom 12 can simultaneously form a top 13 to an underlying turn of the channel 10. The channel 10 further has a closure 15 on one of its side over the product-bearing base 11 of the conveyor belt 2 closure 16 on its other side below the product-bearing base 11. The conveyor belt 2, which essentially consists only of the product-bearing base 11, is supported on helically extending support rails 17. The air flow through the duct 10 is illustrated by arrows. and a 504 172 10 15 20 25 30 35 The embodiment of the device according to the invention shown in Fig. 4 corresponds to that in Fig. 3 only with the difference that the conveyor belt 2 in Fig. 4 has side portions 18 and 19 for safe retention of the products. on the conveyor belt 2. The side portion 18 may be excluded. The side portion 19 must be gas permeable, for example pierced.

In the embodiment of the device according to the invention shown in Fig. 5, the channel 10 has, as before, a gas-impermeable bottom 12 and top 13 as well as the gas-impermeable closure 16 below the product-carrying base 11. In this embodiment, however, the gas-impermeable closure 15 is not stationary, ie not connected to the top 13, but instead forms part of the conveyor belt 2 and is connected to the product-carrying base 11 at one side edge thereof. The closure 15 thus forms a side portion of the conveyor belt 2. As in Fig. 3 and Fig. 4, the conveyor belt 2 in Fig. 5 is mounted on helical support rails 17.

The embodiment of the device according to the invention shown in Fig. 6 corresponds to that shown in Fig. 5, except that the conveyor belt 2 in Fig. 6 has the gas-permeable side portion 19 at the closure or side portion 15 opposite the side of the conveyor belt 2.

In the embodiments of the device according to the invention shown in Figs. 7-9, the channel 10 is formed by the conveyor belt 2 and a second conveyor belt 20, which form both the bottom 12 and the top 13 of the channel 10.

In the embodiment according to Fig. 7, the second conveyor belt 20 thus forms the gas-permeable bottom 12 and top 13 of the duct 10 and furthermore the gas-permeable closure 16 at one side of the duct 10 below the product-carrying base 11. The conveyor belt 2 here has the same design as in Fig. 5. and thus forms the gas-impermeable closure 15 of the channel 10 over the product-supporting base 11. In this embodiment, the two conveyor belts 2 and 20 can be supported by their respective fixed, helical rails 17 and 21, respectively, but alternately natively, the conveyor belt 2 can support the conveyor belt 20 at one side thereof by means of the closure or side portion 15 and the conveyor belt 20 can support the conveyor belt 2 at the other side via its closure 16, which thus forms a side portion of the conveyor belt 20.

The embodiment of the device according to the present invention shown in Fig. 8 corresponds to that shown in Fig. 7, except that the second conveyor belt 20 at its side opposite to the closure or side portion 16 has a gas-permeable side portion 22.

In this embodiment, the conveyor belt 2 can thus be completely supported by the conveyor belt 20 via its gas-permeable side portion 16 and gas-permeable side portion 22.

The embodiment of the device according to the invention shown in Fig. 9 is the preferred embodiment and corresponds to the embodiment shown in Fig. 8 only with the difference that also the conveyor belt 2 has the design shown in Fig. 6, i.e. a gas-permeable side portion 19. on the opposite side to the gas-permeable side portion 15. In this embodiment, the conveyor belt 2 carries an overlying part of the second conveyor belt 20, which in turn carries an overlying part of the conveyor belt 2. Thus, no separate support rails are needed here for forming of the tape stack 3.

As shown in Figs. 3-9, air which is led in radially towards one side of the duct 10 will pass in the radial direction through the gas-permeable part of this side, then pass substantially vertically through the product-carrying base 11 and finally pass in the radial direction out. through the gas permeable portion of the other side of the channel 10.

All turns of the strip stack can thus be said to be connected in parallel in this case.

However, the device according to the invention enables a number of combinations of parallel and series connections of different sections of the channel 10 in the strip stack 3. As illustrated in Fig. 10, a plurality of gas flow channels 23 can thus form means for controlling the gas flow and comprise gas-tight shields 24, which are located in the radial plane through the hollow cylinder or stack 3 and are connected to the outside or inside thereof. Through the gas flow ducts 23 air is supplied to the different sections of the duct 10 and each gas flow duct 23 may contain its own gas conditioning unit 25, so that air with suitable properties, eg a certain temperature, can be supplied to the respective sections of the duct 10 in stack 3. On the side of the cylinder or stack 3 opposite the shields 24 there is a manifold 26, leading to the fan 4, to the conditioning units 25 of the various flow channels 23, from which the air is in turn passed. an embodiment of means for controlling the gas flow, where a common conditioning unit 27 is used in an inlet duct 28 to a section of the duct 10, which section may comprise several turns of the duct 10. By means of transfer ducts 29 the air flow is then guided in series through different section of the duct 10 and then returned to the fan 4.

It will be appreciated that it is thus possible with the device according to the invention to connect areas or sections of the helical channel 10 in series and / or in parallel with each other. The series-connected areas or sections can in this case be mutually downstream or countercurrent or even alternating downstream and countercurrently seen in the direction of the conveyor belt 2 for moving the products. The conveyor belt 2 can of course also move either upwards or downwards in the stack 3.

It is also possible to form a plurality of separate flow paths, each with its own fan and each conditioning unit, by using separate gas flow channels, which are connected to separate sections of the helical channel 10.

It will be appreciated that several modifications of the above-described embodiments of the device according to the invention are possible within the scope of the invention, as defined by the appended claims.

Claims (11)

504 10 15 20 25 30 35 172 1 ° PATENT REQUIREMENTS Device for gas treatment of products, comprising a housing (1), a fan (4) treatment gas in the housing and a conveyor belt (2) with a pierced, product-carrying base (II) the products through the housing, which conveyor belt to a part circulation of to move its length follows a helical path in the housing, characterized by a channel (10) with a substantially rectangular cross-section and with the same helical shape as the conveyor belt conveyor belt in its helical path with the product-bearing base (11) located between the bottom (12) of the channel and the top (13), which bottom and top of the channel are closed, (2) helical path for accommodating which channel has a closure (15: 16) on its one side above and on its other side below it product-supporting base, and which sides of the duct are otherwise gas-permeable, and by means (6-8) for controlling the gas flow in radial direction relative to a hollow cylinder formed by the duct, so that the gas flow passes through this via the perforated, product-bearing base of the conveyor belt in series with the gas-permeable parts of the sides of the duct next to the product-bearing surface. Device according to claim 1, characterized in that the bottom (12), top (13) of the channel are stationary. t e c k n a d of and (15, 16) are Device sides according to claim 2, characterized in that the conveyor belt (2) has at least (18, 19). Device according to claim 1, feel - (10) side closure (15) over the product-carrying base (11) forms part of a gas-permeable side portion characterized in that the channel band (2) of the duct 10 15 20 25 30 35 U 504 172 and thus is mobile along with this. Device according to claim 4, characterized by one with the product moving conveyor belt (2) which is movable together with the product moving conveyor belt and forms the bottom, top and side closure (16) of the duct (10) below the product supporting base ( 11). Device according to Claim 5, characterized in that the product-conveying conveyor belt (2) has a gas-permeable side portion (19) on the side opposite its side closure (15). Device according to claim 5, characterized in that the second conveyor belt (20) has a gas-permeable side portion (22) on the side opposite it to its side closure (16). Device according to claim 7, characterized in that each conveyor belt (2:20) carries an overlying part of the other of the conveyor belts (20; 2). Device according to any one of claims 1-8, characterized in that the means for controlling the gas flow comprise gas-tight shields (24), which are located in radial plane through the hollow cylinder (3) and interleaved, second conveyor belts (20), connected to at least one of its outside and inside for supplying gas with different properties to different parts of the product moving conveyor belt (2). , Device according to claim 9, characterized in that the means for controlling the gas flow comprise a plurality of gas flow channels (23) for connecting sections of the helical channel (10) in series and / or parallel to each other. 11. ll. Device according to claim 9, characterized in that a plurality of separate gas flow channels are provided for copying the means for controlling the gas flow 12 504 172 to each section of the helical channel (10).