JPH064715Y2 - Plate-shaped kamaboko heating device - Google Patents

Description

[Detailed Description of the Invention] Industrial Field of Application This invention is intended to produce a fish paste, which is produced by molding a fish paste such as fish meat on a plate and producing the product with the plate. The present invention relates to a device for heating surimi by Joule heat generated by energizing surimi on a plate.

2. Description of the Related Art In the manufacturing process of a plate-shaped kamaboko, generally, surimi such as fish meat is kneaded and formed into a predetermined shape on a plate, and then heated. As one of the heating means in this case, recently, it has been attempted to use a heating device that utilizes Joule heat accompanying energization.

In a heating device using Joule heat, it is necessary to bring a pair of electrodes into contact with the surimi formed on a plate and to pass an electric current from the electrodes into the surimi, but the electrodes were pressed directly against the surimi. In this case, there is a problem that the surface of the electrode becomes dirty due to the adherence of the surimi or the salt contained therein, the electrode surface is corroded or oxidized, and the surimi itself becomes dirty. Therefore, it has been considered to interpose a water-permeable film such as cellophane between the surimi and the electrode. In this case, if the water-permeable film is previously dipped in water and moistened, the film is removed from the electrode. The surimi can be energized via the water, and when the surimi itself contains a large amount of water, the water in the surimi wets the water-permeable film, and the surimi can be energized from the electrode through the film. And if a water-permeable film is interposed between the electrode and the surimi in this way,
Since the electrode does not come into direct contact with the surimi, it is possible to prevent dirt from the surimi from adhering to the electrode surface, prevent corrosion and oxidation of the electrode surface, and prevent the surface of the surimi itself from becoming dirty.

By the way, as a food material heating device by Joule heat generation in which a water-permeable film is interposed between an electrode and a food material such as fish meat as described above, the present inventors have already disclosed in Japanese Patent Laid-Open No. 3-103155 (Japanese Patent Application No. 3-103155). (Head 1-314340)
In the above, an apparatus as schematically shown in FIGS. 11 and 12 is proposed.

That is, in FIGS. 11 and 12, the plate-shaped kamaboko 1 as a food material, which has been molded, is placed on a tray 2, and the tray 2 is slidably placed on a horizontal traveling bed 31. . Tray guides 32 for guiding the side surface of the tray 2 are provided at upper portions on both sides of the traveling bed 31. By pushing the tray 2 horizontally by a pusher (not shown), the tray 2 can be intermittently moved along the horizontal direction (that is, the direction perpendicular to the paper surface of FIG. 11). Therefore, the tray 2 on which the plate-shaped kamaboko 1 is placed, the traveling bed 31, and the tray guide 32 form a conveyance system path for conveying the plate-shaped kamaboko 1 in the horizontal direction. As shown in FIG. 12, the tray 2 has a plurality of recesses 2A formed along the width direction (that is, the direction orthogonal to the transport direction) on its upper surface, and one recess is provided in each recess 2A. Each one is made to hold and hold the plate-shaped kamaboko 1. The width W of this tray 2 is the length L of the plate-shaped kamaboko 1
The plate-shaped kamaboko 1 is placed so that both ends of the plate-shaped kamaboko 1 project outward from both edges of the tray 2 in the width direction.

A pair of electrodes 3A and 3B are arranged on both sides of a predetermined position in the transport system path in the horizontal direction so as to face both sides of the plate-shaped kamaboko 1 on the tray 2 in the horizontal direction.
A and 3B are forward / backward drive mechanisms 4 such as fluid pressure cylinders.
A and 4B are configured so that they can be moved toward and away from each other. Further, a strip-shaped long water-permeable film 5A, 5B made of cellophane or the like is disposed between the transport system path and the left and right electrodes 3A, 3B so as to be vertically movable. This water permeable film 5
A and 5B are drawn out from the feeding rolls 6A and 6B arranged below the electrodes 3A and 3B, pass through the water tanks 7A and 7B for wetting, and then the electrodes 3A and 3B and the plate-shaped kamaboko 1 to the position between the electrodes 3A, 3
Winding rolls 8A and 8B arranged above B are wound up.

Here, if the electrodes 3A and 3B are moved forward as shown by the phantom line in FIG. 11 with the tray 2 stopped and the water permeable films 5A and 5B stopped, the plate-shaped kamaboko 1 The electrodes 3A, 5A, 5B with the water-permeable films 5A, 5B on both sides of the surimi 1B on the plate 1A in FIG.
3B is pressed, current flows from the electrodes 3A, 3B through the water-permeable films 5A, 5B into the surimi 1B, and is electrically heated. After heating, the electrodes 3A and 3B are retracted, and then the winding rolls 8A and 8B are rotated by a predetermined number of rotations or rotation angles.
B runs upward by a predetermined distance and its water-permeable film 5
The unused portions of A and 5B are located at the portions corresponding to the electrodes 3A and 3B. Therefore, when a new plate-shaped kamaboko is placed between the electrodes by the tray 2 along the transport system path and the surimi of the plate-shaped kamaboko is heated electrically, it is not used in the water-permeable film. A new part will be sandwiched between the electrode and the surimi. In other words, each time the electric heating is performed once, an unused portion of the water-permeable film that is not soiled is used, so even if the water-permeable film is soiled by contact with surimi, the soiling will not occur. It is possible to prevent the situation that the accumulated electricity does not adversely affect the next energization heating, and that the dirt of the film adheres to the electrode and the surface of the electrode is corroded or oxidized.

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention As described above, the plate-shaped kamaboko heating device by electric heating shown in FIGS. 11 and 12 has excellent advantages.
The inventors of the present invention repeated experiments and examinations for its practical use, and found that the following problems exist.

That is, in the apparatus shown in FIG. 11 and FIG. 12, a tray is used as a transport member for placing a plate-shaped kamaboko and transporting it horizontally, and the tray is pushed by a pusher to move forward. However, in such a configuration, at the outlet side of the heating device, after discharging the plate-shaped kamaboko after completion of energization heating from the tray, a separate tray is returned to return the empty tray to the inlet side of the heating device. Therefore, there is a problem that the apparatus is complicated and the number of drive sources is large. In addition, such a complicated device and a large number of power sources cause an increase in cost and troublesome maintenance and inspection. Furthermore, in the equipment that handles food materials such as Kamaboko with a plate, since it is strictly required to be clean from the viewpoint of hygiene management, it is necessary to perform regular cleaning and sterilization. The complicated device causes a problem that cleaning and sterilization are not easy at all.

Further, the device using the tray as described above is of a system in which the tray with the plate is moved along with the tray, and in such a system, the plate with the tray is orthogonal to the transfer direction. In order to prevent it from being inclined with respect to the direction, it is necessary to make the width of the recessed portion on the upper surface of the tray on which the plate-shaped kamaboko is held the same as the width of the plate-shaped kamaboko. Therefore, in order to perform energization heating for plate-shaped kamaboko with different widths, it is necessary to use trays with different recess widths.Therefore, in this case, prepare various types of trays with different recess widths in advance. Since it has to be kept, the cost is inevitably increased.

The present invention has been made in view of the above circumstances, and improves the plate-shaped kamaboko heating device as shown in FIGS. 11 and 12 to simplify the device configuration, particularly the configuration for transportation. In addition to cost reduction, cleaning and sterilization can be easily performed, and also for heating Kamaboko with different widths, it is possible to perform energization heating with the same device configuration without changing parts. It is an object of the present invention to provide a kamaboko heating device with a plate.

Means for Solving the Problems In order to solve the above-mentioned problems, in the present invention, the plate-shaped kamaboko formed is configured to be conveyed horizontally along a predetermined conveyance system path, and the conveyance system A pair of electrodes that can move toward and away from each other is arranged on both sides of a predetermined position in the path in the width direction. Arrange a water-permeable film that is wound by the winding roll, the surimi on the plate of Kamaboko with a plate at the predetermined position of the transport system path by the pair of electrodes with the water-permeable film in the middle In the plate-shaped kamaboko heating device that is sandwiched from both sides and heated the surimi by electric heating, a walking beam transfer mechanism is used as a means for horizontally transferring the plate-containing kamaboko. It is characterized by that.

In this invention, the water-permeable film may be any thin film having properties including water such as cellophane, paper, cloth, non-woven fabric, etc., and is usually a hydrophilic film, a water-absorbent film, or a water-retaining film. Various film materials or film materials, which are also referred to as a flexible film, can be used. In this specification, these films are collectively referred to as a water-permeable film.

Operation In the plate-shaped kamaboko heating device of the present invention, a walking beam transfer mechanism is used as a transfer means for transferring the plate-added kamaboko in the horizontal direction. In this walking beam transfer mechanism, an object to be transferred (a plate-shaped kamaboko in this invention) is placed on a support rail, and a circular motion of a beam arranged so as not to cross the support rail is drawn by a circulating operation. The transported object is intermittently advanced.

In such a walking beam transfer mechanism, the beam itself merely repeats the circulation operation of drawing a rectangular shape. Therefore, as in the case where the tray shown in FIGS. It is not necessary to return the conveying member to the inlet of the conveying path from another outlet by another return means. Therefore, the device configuration is simplified and the number of drive sources is small. In addition, cleaning and sterilization are facilitated as the device configuration is simplified. Furthermore, since the plate-shaped kamaboko is directly advanced by the beam, it can be applied to plate-shaped kamaboko of different widths without any trouble.

Embodiment FIG. 1 shows a plan view of the overall arrangement of a plate-shaped kamaboko heating device according to an embodiment of the present invention, and FIG. 2 shows a walking beam transfer mechanism 4 as a transfer means used in the heating device.
1 is shown.

In FIG. 1, a walking beam transfer mechanism 41 as a transfer means penetrates through the heating device main body 40 from outside the inlet 40A to outside the outlet 40B.
As shown in detail in FIG. 2, the walking beam transfer mechanism 41 includes a beam 43 for forward movement between the two support rails 42A and 42B parallel to each other in the transfer direction. And the beam 43 is driven by a driving mechanism 44. The beam 43, a plurality of actuating projection portion 43A having a predetermined height, which protrude formed on the upper surface at predetermined pitch P, the arrow S ₁ in FIG. _2, S _2, S
_3, as indicated by S _4, and is configured for movement in a rectangular shape in the longitudinal direction (conveying direction) and a parallel plane perpendicular. Here, the pitch P of the operating protrusions 43A in the beam 43 is set so that the interval between the adjacent operating protrusions 43A is sufficiently larger than the width Q of the normal plate-shaped kamaboko 1. Further, the beam 43 is set such that the upper end of the protrusion 43A is located below the upper surfaces of the support rails 42A and 42B in a normal state (in a non-operating state = down state). Further, the beam 43 is determined so that the upper end of the protrusion 43A is located above the upper surfaces of the support rails 42A and 42B and below the upper surface of the plate 1A of the plate-shaped kamaboko 1 in the ascended state, and in the horizontal direction. The forward distance (= backward distance) is set to be equal to the pitch P.

3A to 3D show the operation of carrying the plate-shaped kamaboko 1 by the walking beam carrying mechanism 41 as described above.
First, as shown in FIG. 3 (A), with the upper end of the actuating projection 43A of the beam 43 positioned below the upper surfaces of the support rails 42A, 42B, the plate-shaped kamaboko 1 is mounted on the support rails 42A, 42B. Place it. Then, the beam 43 is raised as shown by the arrow S ₁ in FIG. This raised state is shown in FIG. 3 (B). Then, as shown by an arrow S ₂ in FIG.
If it is moved forward by a distance equivalent to, the plate-shaped kamaboko 1 is pushed by the front surface of the operation projection 43A, and the support rails 42A,
Slide on 42B and move forward by a distance corresponding to pitch P. FIG. 3 (C) shows a state in which the forward end is reached. Then, the beam 43 is lowered as shown by an arrow S ₃ in FIG. The state of the descending end is shown in FIG. Next, the beam 43 is retracted by the distance of the above-mentioned touch P, as indicated by the arrow S ₄ in FIG. 3 (D). This returns to the state of FIG.

In this manner, the plate-shaped kamaboko 1 on the support rails 42A and 42B is intermittently advanced by the distance corresponding to the pitch P by the rectangular circulation operation of the beam 43. In addition, here, the edge portion on the upper end front surface side of the operation projection 43A is chamfered 43B in a curved shape. By chamfering the operation protrusion 43A in this manner, it is possible to prevent the operation protrusion 43A from lifting the plate-shaped kamaboko 1 when the beam 43 moves up.

Referring back to FIG. 1 again, the walking beam transfer mechanism 4
1, a supply belt conveyor 45 is disposed on the side of the outside of the inlet 40A of the heating device main body 40, and these walking beam transfer mechanism 41 part and belt conveyor 45 part It is located in parallel.

The supply belt conveyor 45 is an endless annular belt 4.
6, a flexible material such as a synthetic resin is used, and the belt 46 has a driving mechanism 47 such as a motor.
It is designed to be cycled around. Belt 4
As shown in detail in FIG. 4, reference numeral 6 denotes a large number of groove-shaped recesses 46A formed along the width direction at predetermined intervals in the length direction (conveying direction). Each recess 46A has a plate. The kamaboko 1 is placed and held. Then, the plate-shaped kamaboko 1 on the conveyor 45 is pushed to the side of the portion where the walking beam transfer mechanism 41 and the supply belt conveyor 45 are arranged in parallel outside the entrance 40A of the heating device body 40 to transfer the walking beam. A supply pusher 48 for transferring onto the support rails 42A and 42B of the mechanism 41 is provided. On the other hand, on the side of the walking beam transport mechanism 41 outside the outlet 40B of the heating device body 40, the walking beam transport mechanism 41 is provided.
An ejecting pusher 49 for extruding and ejecting the plate-shaped kamaboko 1 on the support rails 42A and 42B is provided.

In FIGS. 1 to 4 described above, the plate-shaped kamaboko 1 sent from the molding device 50 for molding the surimi 1B on the plate 1A is on each recess 46A on one end side of the supply belt conveyor 45. And is transported to a position aligned with the walking beam transport mechanism 41 by the belt conveyor 45. Then, the supply pusher 48 slides the recess 46A of the belt conveyor 45 onto the support rails 42A and 42B of the walking beam transfer mechanism 41. Then, by the operation of the beam 43 as described above, the support rails 42A and 42B are intermittently advanced, fed into the heating device main body 40 from the inlet 40A, and after the heating is finished, they are guided to the outside through the outlet 40B, and the discharge pusher 4
9 pushes the support rails 42A and 42B laterally, discharges them, and sends them to the next step.

FIG. 5 shows the entire structure of the heating device main body 40, and FIGS. 6 to 9 show enlarged main parts thereof.

In FIG. 5, on both sides of a predetermined position (positions corresponding to electrodes 3A and 3B described later) of the transfer system path defined by the walking beam transfer mechanism 41 in the heating device main body 40, the plate-shaped kamaboko 1 is attached. Stoppers 13A and 13B for restricting both end positions of the plate 1A are provided. These stoppers 13A and 13B are made of synthetic resin or the like in the shape of a long plate as a whole, and the vicinity of the upper edge is in contact with the end surface of the plate 1A of the plate-shaped kamaboko 1, and the plate-shaped kamaboko 1 is in the longitudinal direction thereof. (Therefore, it is regulated so as not to move in the width direction of the transport system path). The stoppers 13A, 13
B has a slightly curved plate surface, and elastically has a plate-shaped kamaboko 1
The plate 1A is pressed.

Further, support rails 42A, 4 are provided on both sides in the width direction of the transportation path defined by the walking beam transportation mechanism 41.
A pair of electrodes 3A and 3B are arranged in opposition so as to face the surimi 1B of the plate-shaped kamaboko 1 on 2B. These electrodes 3A and 3B are driven by advancing and retracting drive mechanisms 4A and 4B composed of fluid pressure cylinders and the like. It is configured so that they can be moved in the directions of approaching and separating from each other. Furthermore, electrode 3A,
Between the plate 3B and the plate-shaped kamaboko 1 on the support rails 42A, 42B, plate-shaped long water-permeable films 5A, 5B made of cellophane or the like are arranged in a vertically movable state. These water-permeable films 5A and 5B are drawn out from the lower pay-out rolls 6A and 6B, respectively, and wound in the upper take-up rolls 8A and 8B to run in the vertical direction. Below the electrodes 3A, 3B is a water tank 7A,
7B is arranged, and the water-permeable films 5A and 5B drawn from the feeding rolls 6A and 6B are the guide rolls 1
It is guided by 5, 16 and immersed in the water tanks 7A, 7B, pulled up from the water tanks 7A, 7B and wound up by the winding rolls 8A, 8B.

The winding rolls 8A and 8B are constituted by hollow paper tubes, as shown in detail in FIGS. 6 and 7. The take-up rolls 8A and 8B are a pair of support rolls 16A and 16B arranged in parallel so as to be close to each other.
B; It is placed in a free state on the upper surface side between 17A and 17B. Support rolls 16A, 16B; 17A, 17
B is a taper-shaped collar portion 1 at both ends of the outer peripheral surface thereof.
8 and 19 are formed, and the brim portions 18 and 1 thereof are formed.
The winding rolls 8 </ b> A and 8 </ b> B are mounted on the outer peripheral surface between the spaces 9. And these support rolls 16
A drive roll 20 having a large surface friction coefficient, such as a urethane rubber roll, is in contact with the lower surface side between A, 16B; 17A, 17B, and this drive roll 20 is rotated by a rotary drive mechanism 21 such as a motor. It is like this. The support rolls 16A, 16B; 17A, 17B
The support shafts 22 protruding from both ends of the frame body 2 respectively.
It is rotatably supported in a state of being engaged with 3, and the distance between the frame 23 and the lower fixed base 24 can be adjusted by an adjusting bolt 25. That is, the support roll 16
The vertical position of A, 16B; 17A, 17B can be adjusted so that these support rolls come into contact with the drive roll 20 at an appropriate contact pressure. In the illustrated example, a cylindrical weight 26 having an outer diameter remarkably smaller than its inner diameter is rollably arranged inside the winding rolls 8A and 8B. This weight 26 has flanges 26A at both ends so as not to separate from the winding rolls 8A and 8B.
Are formed.

On the other hand, the feeding rolls 6A and 6B are the winding rolls 8A and 8B.
Like the above, it is composed of a hollow paper tube, and the water-permeable films 5A and 5A are preliminarily formed on the feeding rolls 6A and 6B.
B is wrapped. Each of the feeding rolls 6A and 6B has an eighth
As shown in the figure, it is externally inserted on a rotatable holding roll 27 that is horizontally supported between a pair of side plates 28. The outer diameter of the holding roll 27 is made much smaller than the inner diameter of the feeding rolls 6A and 6B.

In the above heating device main body 40, at the start of operation, it is necessary to bridge the water permeable films 5A and 5B from the feeding rolls 6A and 6B to the winding rolls 8A and 8B. At this time, first, the feeding rolls 6A and The water permeable films 5A and 5B are pulled out from 6B and the guide rolls 15 and 1
6 is immersed in the water tanks 7A and 7B via 6 and is further pulled up to be wound around the take-up rolls 8A and 8B by one or more layers, and the take-up rolls 8A and 8B are directly supported by the support rolls 16A and 16B.
B; it may be placed on 17A and 17B. At this time, the winding direction with respect to the take-up rolls 8A and 8B may be determined as shown in FIG. 9 (note that FIG. 9 shows one take-up roll 8A).
Is shown, and the other take-up roll 8B is symmetrical with FIG. 9).

As described above with reference to FIGS. 1 to 4, the walking beam transport mechanism 41 is used to electrically heat the plate-mounted kamaboko 1 by the heating device main body 40 as described above.
The beam 43 is driven with the plate-shaped kamaboko 1 placed on the support rails 42A and 42B, and thereby the plate-shaped kamaboko 1 is intermittently conveyed horizontally and stopped at a position between the electrodes 3A and 3B. In this manner, when the plate-attached sushi 1 is stopped between the electrodes 3A, 3B, the plate-attached sushi 1 comes into contact with the stoppers 13A, 13B at both end faces of the plate 1A.
Next, the electrodes 3A and 3B are moved forward as in the prior art, and the electrodes 3 are sandwiched with the water-permeable films 5A and 5B in between.
A and 3B are pressed into contact with the left and right sides of the surimi 1B portion of the plate-shaped kamaboko 1 to energize.

After the electric heating is completed, the electrodes 3A and 3B are retracted. At this time, the water-permeable films 5A and 5B also return to the original state, but even if the water-permeable films 5A and 5B stick to the surimi 1B portion of the plate-shaped kamaboko 1, the plate 1
Since both ends of the portion A are regulated by the stoppers 13A and 13B, the plate-shaped kamaboko 1 remains attached to it as the water-permeable films 5A and 5B return, and the width direction of the conveyance system path (the length direction of the kamaboko) ) Is prevented from moving to
Of course, the plate-shaped kamaboko 1 does not drop from the support rails 42A and 42B.

After this, as indicated by the arrow in FIG. 9 with respect to one of the water-permeable films 5A, if the drive roll 20 is rotated by a predetermined number of revolutions, the support roll 1 pressed against the drive roll 20 is rotated.
6A and 16B rotate, and their supporting rolls 16A and 16B
Winding roll 8 in contact with the water-permeable film 5A
A rotates by the frictional force to wind up the water-permeable film 5A by a predetermined amount, and the water-permeable film 5A between the electrode 3A and the plate-shaped kamaboko 1 is pulled upward by a predetermined distance. Of course, the same applies to the other water-permeable film 5B.

In the embodiment shown in FIG. 1, the plate-shaped kamaboko 1 after molding
Is temporarily received by the supply belt conveyor 45, and the walking beam transfer mechanism 41 is further received from the belt conveyor 45.
It is transferred to the heating device main body 40,
In some cases, the supply belt conveyor 45 may be omitted, and the molded plate-shaped kamaboko 1 may be directly placed on the support rails 42A and 42B of the walking beam transfer mechanism 41.

The walking beam transport mechanism 41 is not limited to the configuration shown in FIG. 2 and may have the configuration shown in FIG. 10, for example. That is, in the example of FIG.
Two beams 43 are arranged in parallel, and a support rail 42A is arranged between the two beams 43. In this case, it goes without saying that the two beams 43 need to be driven in synchronization.

In this way, the support rail and the beam only need to be arranged so as not to interfere with each other, and the number and arrangement order of each can be arbitrarily determined.

Effect of the Invention According to the plate-shaped kamaboko heating device of the present invention, the plate-shaped kamaboko is conveyed horizontally and the electrodes are inserted from both sides with a water-permeable film interposed between them at a predetermined position of the conveying system path. When pressing the surimi and heating it with electricity, the walking beam transfer mechanism is used as a means to place and transfer the plate-shaped kamaboko, so it is similar to the previously proposed device using a tray. The device does not become complicated due to the return of the conveying member, so that the cost can be reduced and the maintenance and inspection can be facilitated.
In addition, it is possible to easily and easily perform the washing and sterilizing work that are indispensable as a device for handling food materials, and to always maintain a clean state.In addition, it is also possible to transport the kamaboko with plates of different widths with the same device. Therefore, unlike the previously proposed device, the cost is not increased because many types of trays are prepared.

[Brief description of drawings]

FIG. 1 is a plan view showing the entire construction of an example of a plate-shaped kamaboko heating device of the present invention, FIG. 2 is a perspective view showing a walking beam transfer mechanism used in the device of FIG. 1, and FIG. ) To (D) are schematic diagrams for explaining the operation of the walking beam transport mechanism shown in FIG. 2, and FIG.
FIG. 5 is a perspective view showing a supply belt conveyor used in the apparatus shown in FIG. 5, FIG. 5 is a front view of a heating apparatus main body used in the plate-shaped kamaboko heating apparatus of the present invention, and FIG. 6 is winding in the heating apparatus main body shown in FIG. VI-VI line enlarged cross section near the take-up roll, No. 7
6 is a front sectional view taken along line VII-VII in FIG. 6, and FIG. 8 is VIII in the vicinity of the feeding roll in the heating apparatus main body in FIG.
FIG. 9 is an enlarged cross-sectional view taken along line VIII, FIG. 9 is a schematic view showing a winding direction of the water-permeable film on the right winding roll and a rotating direction of each roll in the heating device main body of FIG.
FIG. 0 is a perspective view showing another example of the walking beam transfer mechanism used in the device of the present invention, FIG. 11 is a schematic diagram of the plate-shaped kamaboko heating device proposed prior to the present application, and FIG. It is a perspective view which shows the tray in the apparatus of a figure. 1 ... Kamaboko with plate, 1A ... Plate, 1B ... Surimi, 3A, 3B
... Electrodes, 4A, 4B ... Forward / backward drive mechanism, 5A, 5B ... Water-permeable film, 6A, 6B ... Delivery roll, 8A, 8B ...
Winding roll, 40 ... Heating device main body, 41 ... Walking beam transport mechanism, 42A, 42B ... Support rail, 43 ...
beam.

Claims (1)

[Scope of utility model registration request] 1. A kamaboko with a plate formed is configured to be conveyed in a horizontal direction along a predetermined conveying system path, and on both sides in the width direction at a predetermined position in the conveying system path, approaching and separating from each other. Arrange a pair of electrodes that can move in the direction, arrange the water-permeable film that is drawn from the lower pay-out roll and wound by the upper take-up roll, respectively, between the transport system path and each electrode, A plate that sandwiches the surimi on the plate of the plate-shaped kamaboko at the predetermined position of the transport system path from both sides by the pair of electrodes with the water-permeable film interposed in between, and heats the surimi by electric heating In the attached kamaboko heating device, a walking beam transport mechanism is used as a means for horizontally transporting the plate-attached kamaboko.