NL8801060A - DEVICE FOR COOKING SHRIMPS. - Google Patents

Description

T-4 / Sterkos

DEVICE FOR COOKING SHRIMPS

The invention relates to a device for cooking shrimps, comprising a water container, a heating device for heating water in the water container / a transport device provided with supply and discharge means / for transporting the shrimps through the water container .

Such a device / in which the transport device is formed by a belt conveyor / which guides the shrimp in separate compartments through the water in a water container / is known. This known device is relatively complicated by the guide and drive means for the conveyor belt.

The object of the invention is now to provide a device of the type described in the preamble / which is of simple construction.

With a device according to the invention this is achieved in that the transport device comprises a transport screw with a horizontal rotation axis. As a result, the device need only comprise a single moving part / so that it can be of simple construction. The movement is then still a constructively favorable rotational movement.

A preferred embodiment of the device is characterized in claim 2. Due to the drum wall that moves in one piece, the shrimps are in a certain way transported well through the device / without the danger of being damaged between wall parts moving relative to each other.

Preferably, the measure as set out in claim 3 is further applied here, which has the advantage that a very good water circulation occurs / as a result of which the boiling process can take place in a reliable manner.

A very favorable embodiment is characterized in claim 4. As a result of this, the device is in principle given a very simple construction, whereby a good and reliable operation is ensured.

A favorable further development of the invention is characterized in claim 5. The use of a dosing drum ensures that the correct amount of shrimp is introduced into the screw conveyor per revolution, so that clogging and the consequent loss of a batch of shrimp are prevented. The device can hereby function reliably without any supervision.

A constructionally favorable embodiment is characterized in claim 6.

A construction which further contributes to the object of the invention in that it can be realized with relatively simple means, is apparent from claim 7. The conveyor screw in this embodiment is advantageously composed of flat wall parts, which can be easily joined together by welding .

With the measure of claim 8 it is advantageously achieved that each time, with each revolution, all shrimps are transported in the direction of transport parallel to the axis of rotation. All shrimps experience the same cooking process, so that the end product is of uniform quality.

The invention will be further elucidated in the following description with reference to the exemplary embodiments shown in the figures.

Fig. 1 shows a partly broken away perspective view of an exemplary embodiment of the invention.

Fig. 2 shows a partial perspective view of the dosing drum of the device of FIG. 1.

Fig. 3 shows in partly broken away perspective view the device of fig. 1 according to arrow III in fig. 1.

The device 1 of fig. 1 comprises a water trough 2 which, as shown, can have a simple box shape. The front wall 9 and the rear wall 12 of the water trough 2 are parallel to each other, 8801060 ft 3. Although not shown, a sealing cap can be placed on the water tray 2, since as will be described hereinafter, the supply and discharge of boiled or boiled shrimps to be cooked takes place through the front wall 9 and 5 back wall 12.

A heating device 3 is arranged at the bottom of the water trough 2. It can be designed in various ways and, for example, comprise a heat exchanger, so that, for example, waste heat can be used for heating the cooking water in the container 2. The heating device 3 can also comprise an enclosed burner which gives its heat directly to the cooking water.

In the water trough 2 a rotation axis 5 is mounted horizontally, which carries a transport screw 4. The transport screw 4 is composed of a number of flat disks 7 arranged parallel to each other and evenly spaced, on the periphery of which a fixed drum 6 is arranged. The discs 7 each comprise a radial slot which, in the shown exemplary embodiment, has a width which substantially corresponds to the distance between adjacent discs 7, while in addition the shaft has the same width. Sloping connecting walls 8 are welded between obliquely opposite slit edges of adjacent discs 7. The connecting wall parts 8 close with their end walls 25 on the shaft 5 and the drum 6, respectively.

Due to this construction of slotted flat disks 6, with slanting intermediate wall parts 8, the spaces between the adjacent disks 7 are contiguous to a substantially spiral shape. The axially extreme discs 7 with the connecting wall parts 8 bear parallel wall parts 18, which are provided with flexible sweeping strips 19. These flexible sweeping strips 19 abut the inner side of the front and rear wall 9, 12 of the water basin 2.

A supply opening 35 is formed in the front wall of the water trough, through which shrimps can be introduced into the first section of the screw conveyor 4. A discharge opening 13 is formed in the rear wall 12, through which the shrimps which have passed the transport screw are discharged.

, 8801080 ___ • 4 *

The shaft 5 protrudes through the front wall 9 of the water trough 2. A metering drum 20 is mounted on the projecting end of the shaft 5. This dosing drum 20 consists, as shown, of two annular discs spaced apart by a drum wall. The drum 20 is mounted on the shaft 5 by means of spokes 25. In the space defined between the annular disks and the drum wall of the dosing drum 20, a dosing bin 21 is formed. This dosing trough has an inlet 22 open in a radial plane in the direction of rotation 10 and an outlet 23 open in the direction towards the axis 5.

In operation, the shaft 5 is driven in rotation in the direction of arrow 28, by means of a drive 15 comprising a reduction gear 16, which with its output shaft is coupled to the rotation shaft 5, and which is coupled to its input with a drive motor 17.

In the operation of the device, shrimps are introduced into the dosing drum 20 via a supply device 14, as indicated by the arrow 29. When the dosing bin 21 is moved upwards from the bottom position, this dosing bin is filled with the supplied shrimps . The excess shrimp present can move along the dosing bin via the passage 24. When the dosing tank 21 moves further upwards, as a result of the rotation of the dosing drum 20, the shrimps are also moved upwards. Near the top point of the circular movement, the shrimps fall out of the outlet 23 of the dosing tank 21 and end up in a funnel 11 arranged around the feed opening 10. This is illustrated with arrows 26 in Figure 2. The action of the dosing drum 20 with the dosing bin 21 thus ensures that with each revolution of the rotary shaft 5 only a maximum amount of shrimp can be introduced into the conveying screw 4. Blockage of the device is certainly prevented in this way.

It will be appreciated that with each revolution of the axis of rotation 5, the shrimp supplied are moved one segment toward the back wall each time a slot in a flat disc 7 is in a .8801060 y 5 position below the axis of rotation. . After three revolutions, the shrimps supplied via the supply opening 10 have arrived in the segment of the transport drum 4 adjacent to the rear wall 12. In the next revolution, the 5 shrimps in the rear segment are taken up by the wall part 18 and the flexible flexible strip attached thereto. 19.

As soon as this wall part 18 with sweeping strip 19 passes the discharge opening 13, the shrimps slide along the oblique surface formed by this wall part 18, through the opening 13 in the receptacle arranged behind the rear wall 12. At the top, water is supplied in this receptacle 30 via the pipe 33. This water has a low temperature, so that the cooked shrimps are immediately cooled. Due to the water flow supplied via the line 33, the shrimp rinse through the funnel 31, which connects at the bottom of the collecting tray 30, into the line 32. The water flow takes the shrimp along to the shrimp outlet 35, including in a usual manner collector can be placed.

The conduit 32 bends back and forth a number of times, such that it is of sufficient length to properly cool the supplied shrimp to the desired low temperature.

To ensure blockage of the transport pipe 32 and a sufficient supply of cold water, additional water supplies 34 are provided. The conduit 32 is bent up again towards the shrimp outlet 35, so that a water seal is formed, which ensures that the shrimps in the conduit 32 are in contact with the cooling and transport water at all times.

The drum wall 6 of the conveyor screw 4 is dimensioned such that the end edges thereof lie close to the inner side of the front and rear wall 9, 12. This distance is preferably a maximum of 2 millimeters. This ensures that on the one hand no shrimp can escape through this gap and on the other hand that no frictional contact of the drum with the wall of the water trough 2 occurs.

As indicated in the drawing, the walls of the conveying screw 4 and of the dosing drum 20 are perforated. Any water that ends up in the dosing drum 20 .8801060 * 6 can escape as a result of this, and will not end up in the water tank 2. The perforations in the transport screw 4 ensure good circulation of the cooking water, as has already been noted. 8801060

Claims (8)

7 » Device for cooking shrimp, comprising a water container / a heating device for heating water in the water container / a transport device provided with feed and discharge means / for transporting the shrimp through the water container 5, characterized in that the transport device a conveyor screw with a horizontal rotation axis. 2. Device as claimed in claim 1 / characterized in that the conveyor screw is formed by a cylindrical drum wall and a / a substantially helical conveyor channel defining / extending from a central axis to the drum wall and fixedly connected thereto. Device according to claim 2, characterized in that the drum and the spiral wall element are perforated. Device as claimed in any of the foregoing claims / characterized in that the end edges of the drum wall, with a slight play after abutting against the inside of a front and rear wall of the water trough / and in the front and rear position / respectively a supply and discharge opening is provided. 5. Device as claimed in claim 4 / characterized in that the rotary axis protrudes through the front wall of the water trough and on its projecting end a dosing drum feeding a maximum quantity of shrimps feeding in the feed opening is provided at each revolution. 6. Device as claimed in claim 5, characterized in that the metering drum comprises a metering hopper open in a radial plane in the direction of rotation and an outlet comprising an open direction towards the axis of rotation 30, and that a feed opening at the supply opening open upwards / a funnel extending over at least the axial distance from the outlet is fitted. .8801060 7. Device as claimed in any of the foregoing claims / characterized in that the spiral wall element comprises a number of flat discs arranged on the shaft at regular intervals in radial planes, each of which has a radial slot with a width corresponding substantially to the distance / and in which oblique connecting wall parts are each arranged between obliquely opposite slit edges of adjacent discs / in order to obtain a substantially spiral shape. 10 8. Device as claimed in claim 1, characterized in that the axially extreme discs with the connecting wall parts bear parallel wall parts / which are provided with flexible sweeping strips in contact with the front and rear wall of the water trough. .8801060