GB2324757A - Ejection apparatus for use in moulding a transverse fan impeller component - Google Patents

Abstract

An impeller unit 26 for a transverse fan comprises a partition plate 25, having a plurality of inclined blades 24 extending therefrom, and is moulded using an upper and lower dies. Once the impeller unit has been moulded, the dies are separated and the finished impeller unit is ejected from the lower die by means of apparatus comprising an ejector block 35 connected to a shaft (33)(fig. 12), having a projection engaging a cam plate (34). The arrangement causes the impeller unit to rotate as it is ejected, thereby avoiding damage to the inclined blades. A plurality of the impeller units my be stacked to form the impeller of a transverse fan.

Description

APPARATUS FOR MANUFACTURING A TRANSVERSE FAN The present invention relates to an apparatus for manufacturing a transverse fan suitable for use as a room fan for air conditioners, more particularly a transverse fan having a structure that a plurality of molded multi blade impellers are sequentially stacked and secured in an axial direction thereof.

A common example of an air conditioner incorporating this type of transverse fan as a room fan is shown in Fig. 17. The air conditioner comprises a room unit 1 having a front surface 2a of a body casing 2 on which a suction grille 3 and a blow-out grille 4 are disposed vertically at the upper and lower portions of Fig. 17, the suction grille 3 and the blow-out grille 4 being allowed to communicate with each other through a ventilating passage 6 formed in a fan casing 6.

The ventilating passage 6 includes a transverse fan 8 serving as a room fan disposed downstream from an indoor heat exchanger 7. Thus, air in the room sucked into the body casing 2 through the suction grille 3 is subjected to heat exchange in the indoor heat exchanger 7, causing cold or hot air to be again sent to outside of the room through the blow-out grille 4 by the transverse fan 8 thereby to cool or warm the room.

The conventional transverse fan 8 of the described type comprises a plurality of elongated blades Sc between a pair of disc-like right and left end plates 8a and 8b, the elongated blades Sc being allowed to run parallel with respect to a fan axis 0 at predetermined pitches in the circumferential direction of the transverse fan 8 as shown in Fig. 18. At intermediate positions in the axial direction of the transverse fan 8, annular partition plates 8d are disposed at predetermined pitches in the axial direction.

The transverse fan 8 constitutes an air blower in association with the fan casing 5 and a nose 9 shown in Fig. 17, the air blower having a suction portion and a blow-out portion adjacent to gaps among the nose 9, the fan causing 5 and the transverse fan 8. These two gap portions are main sources of generating noise of the blower because an exceeding pressure change takes place due to inversion of the air flowing direction with respect to the elongated blades Sc of the transverse fan 8.

Noise is generated due to the pressure change such that noise produced due to the rotation of the fan and indicated by waveform N in Fig. 19A has a peak Pa at a frequency defined by the multiplication of the number of the elongated blades Sc of the transverse fan 8 and the rotational speed of the same and has also a peak Pb at a frequency which is two times the foregoing frequency. Since the waveform of the pressure change takes place rapidly and steeply, harmonic waves (harmonic Pb) having this waveform as the fundamental wave can easily be generated.

Note that Fig. 19A shows the result of analysis of the noise N of the blower generated when the transverse fan 8 having, for example, a diameter of 88 mm and an overall length of 593 mm and comprising 35 elongated blades Sc each running parallel to the fan axis 0 is rotated at a speed of 20 rotations/second.

Although the quantity of air supplied per rotation increases in inverse proportion to the size of the gaps among the transverse fan 8, the nose 9 and the fan casing 5, the pressure change becomes excessive in the gaps. Hence, the rotation noise N is enlarged and the harmonic waves are increased. Although the gaps having small sizes to a certain extent make enlarge the air flow quantity and thus lower the noise level if the same quantity of air is blown, thus improving the blowing performance, and excessive reduction in the sizes of the gaps relatively increases the rotation noise N, causing unpleasant noise to be produced unsatisfactorily. In the conventional structure, therefore, the gaps cannot be made too small.

In a blower using the conventional transverse fan 8 in which the longitudinal portion of each of the elongated blades Sc runs parallel to the fan axis 0, the nose 9 and fan casing 5, which form the blower in association with the transverse fan 8, are constructed to run parallel to the fan axis 0. Therefore, each of the elongated blades Sc passes near each of the gaps between the elongated blade Sc and the nose 9 and between the elongated blade Sc and the fan casing 5. As a result, the overall lengthwise portion of the elongated blade Sc passes through each gap in a short time, thus causing pressure change to take place simultaneously in a space having the length of the elongated blade 8c. Therefore, the total sum of the pressure change by one elongated blade Sc is large and the waveform is distorted excessively, resulting in harmonic waves being easily generated (see Fig. 19A. The distortion of the waveform is changed considerably in accordance with the degree of parallelization of the nose 9, the fan casing 5 and the elongated blades 8c. Such considerable change leads to easy changes of the number and the degree of the harmonic waves. That is, a blower of the type comprising the transverse fan 8 which includes the elongated blades Sc disposed in parallel to the fan axis 0 encounters easy occurrence of individual difference in the harmonic waves of the rotation noise N.

The harmonic waves included in the noise produces unpleasant noise. If the size of the gap from the noise and that from the fan casing 5 is reduced for the purpose of enlarging the air quantity, the sound level of the rotation noise N is raised excessively. Therefore, the gap cannot be reduced satisfactorily and, thus, the air quantity cannot be increased as desired.

Accordingly, the transverse fans respectively disclosed in Japanese Utility Model Publication No.

59-39196, Japanese Utility Model Laid-Open No. 56-2092 and Japanese Utility Model Laid-Open No. 56-45196 have a structure in which blades are disposed in not parallel to the fan axis 0 in order to continuously generate the pressure changes and to prevent the rotation noise N from causing.

In such prior art, a transverse fan 10 shown in Fig. 20 usually has a structure that a plurality of elongated blades 11 are allowed to penetrate a plurality of disc-like partition plates 12, the elongated blades 11 are secured to the plural partition plates 12 and the right and left end plates 13a and 13b, and torsional force is applied so that the elongated blades 11 are plastically deformed.

As an alternative to this technique, a transverse fan 14 shown in Fig. 21 has a structure in which a plurality of elongated blades 15 are applied with external force so as to be twisted and, in this state, the elongated blades 15 are secured to a plurality of partition plates 16 and a pair of right and left end plates 17a and 17b.

A transverse fan disclosed in Japanese Utility Model Publication No. 59-19838 has a structure in which multi-blade impellers having such an arrangement as that in which a plurality of blades running parallel to the axis of the transverse fan are stood upward on either side of the partition plate and receiving grooves are formed on the other side by the same number as that of the blades used, and the leading portions of the blades of the impellers are inserted into the receiving grooves formed in the partition plate for another impeller so as to be connected with each other, thus assembling one transverse fan. The shape of the grooves is formed in such a manner that the leading portions of the blades are twisted in a predetermined direction when the blades are forcibly inserted into the grooves to establish the connection.

(1) However, the conventional transverse fans of the type having the blades that are ,applied with external force so as to be deformed involve excessively large residual stress being left in the material for the blade, thus causing a problem to take place that a desired dimension accuracy cannot easily be realized. As a result, the performance of the manufactured blower cannot easily be made uniform. In addition, the residual stress can be reduced by only annealing that is performed for a long time. In order to prevent stress from being left in the material for the blade, a method may be employed which has the step of forming the blade into a circular arc shape in the longitudinal direction. However, a cutting work required for this purpose involves waste of the material and increasing of the processes in number.

(2) The transverse fan disclosed in Japanese Utility Model Publication No. 59-39196 is assembled in a state where the twisted elongated blades are formed.

Therefore, although the residual stress in the elongated blades can be reduced, the following problem (3) will arise: (3) In general, an external impact applied to the transverse fan causes stress to be concentrated in a portion that establishes the connection between the blade and the partition plate. Therefore, the connection portion can easily be deformed or broken.

Therefore, in the case where the elongated blades can be inserted into the grooves or apertures formed to the partition plates, caulking or bonding working may be employed to surely connect the blades to the partition plates. However, either working suffers from poor strength and rigidity obtained in the connection portion, thus resulting in that the connection portion can easily be plastically deformed even by relatively small external force. Hence, the angle made by the partition plates and the blades connected to one another will easily be changed.

What is worse, the shape of the manufactured blades with respect to the axis of the transverse fan, and in particular, the degree of non-parallelization, cannot be stabilized at the time of manufacturing and, thus, manufacturing errors increase, causing the blowing performance to be scattered exceedingly.

The conventional caulking method usually comprises a step of forming gaps except the caulking points in order to improve the working efficiency, causing axial-directional air flows to be introduced into the gaps for the caulking process because the air flows generated on the surfaces of the blades of the transverse fan collide with the partition plates, thus providing a problem of generating blowing noise.

(4) The transverse fan disclosed in Japanese Utility Model Publication No. 59-19838 has a structure in which the grooves for fixedly receiving the blades by welding are formed into a mortar-like shape so as to be twisted at the time of securing the blades by welding, thus enabling blades having different lengths to be 'manufactured. However, an external force is applied to twist the blades when the molded blades are assembled, resulting in that a problem similar to (1) arises.

SUMMARY OF THE INVENTION An object of the present invention is to substantially eliminate defects or drawbacks encountered in the prior art described above and to provide an apparatus for manufacturing a transverse fan capable of achieving low noise and a high efficiency, enabling the shape of the blade and the length of the transverse fan to be changed easily, exhibiting adequate reliability and reducing the cost.

According to the invention there is provided an apparatus for manufacturing a transverse fan comprising: an ejector block for supporting a partition plate in such a manner that the patition plate is ejected outward from a lower die and having a connection portion detachably connected to a connection portion of the partition plate; an ejector shaft for supporting the ejector block; and a cam plate for upwardly ejecting the ejector block while rotating the ejector block through the ejector shaft after an upper die of a mold for injection-molding the multi-blade impeller is separated from the lower die.

According to the arrangements described herein a plurality of multi-blade impellers are sequentially stacked in the axial direction and thus the transverse fan is integrally formed so that the transverse fan can easily and cheaply manufactured.

Furthermore, the selection of the number of the multi-blade impellers to be stacked will enable the length of the fan axis to be changed easily. Furthermore, the displacement of the multi-blade impellers in the circumferential direction can be also easily made. In addition, the shape of the blade may be arbitrarily set.

Since the plural blades are stood upward, extend axially, on either side of the partition plates, thus being formed to be non-parallel to the fan axis, the pressure generated between the transverse fan having the blades and the nose and between the same and the fan casing can be continuously changed. Therefore, the rotation noise level of the transverse fan can be lowered.

Since each of the partition plates and the blades are integrally molded, the accuracy of the angle made between the mounted blades and the partition plates can stably be improved, thus reducing the scattering in the blowing performance. Furthermore, since the necessity of caulking each blade to the partition plate can be eliminated, the twist angle of the blade can be made larger. Since no gap for caulking is required for the partition plates, the generation of blowing noise due to the introduction of air flows into the gap can be prevented.

Since the plural blades are attached to the partition plates at a plurality of mounting pitches in the circumferential direction, the peak frequency of rotation noise, which has been reduced due to the inclined shape of the plural blades, can be dispersed. Therefore, unpleasant noise level can be lowered and the produced sound quality can be improved.

Since the multi-blade impellers adjacent in the axial direction are displaced by a predetermined angle around the axis, the phase difference can be given to cause sound pressure waves generated between adjacent blades disposed on the two sides of the partition plate to cancel with each other. As a result, the rotation noise, which has been reduced due to the inclined shape of the blades, can further be reduced.

Since the formed blades extend linearly in their longitudinal directions while being inclined at a predetermined angle in the direction of the rotation, the mold for forming the multi-blade impellers can easily be prepared. Furthermore, the tensile and compression strengths of the blades in their longitudinal direction can be improved. Therefore, the friction generated when the multi-blade impeller is ejected from the mold can be prevented and, therefore, the life of the mold can be lengthened.

Furthermore, the strength of the manufactured multi-blade impeller can be improved and the reliability can be improved. Therefore, the thickness of the blade can be reduced, its weight can be reduced and the quantity of air that is blown can be enlarged.

Since the thickness of each blade in the cross section perpendicular to the axis is narrowed from its base toward the leading portion, the frictional force generated when the multi-blade impeller, which has been molded by injection molding, is ejected from the mold can be reduced.

Therefore, ejection can be facilitated and the molding ability can be improved.

Since the multi-blade impeller molded by injection molding is ejected from the mold while being rotated in the direction of the inclination of each blade around the rotational shaft, each blade can easily be ejected while being protected from damage even if each blade is inclined with respect to the partition plate by a predetermined angle. Therefore, the molding ability can be improved and the life of the mold can be lengthened.

The nature and further features of the present invention will be made more clear from the following descriptions made in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS In the accompanying drawings: Fig. 1 is a perspective view which illustrates a transverse fan; Fig. 2 is an exploded perspective view which illustrates the arrangement shown in Fig. 1; Figs. 3A and 3B are detailed enlarged views of Fig. 1; Fig. 4 is a perspective view which illustrates an example of the multi-blade impeller shown in Fig. 2; Fig. 5 is a perspective view which illustrates another example of the multi-blade impeller shown in Fig. 2; Fig. 6 is a bottom view of Fig. 4; Fig. 7 is an enlarged view which illustrates an essential portion of Fig. 6; Fig. 8 is a perspective view of the transverse fan of Fig. 1 having a displacing angle; Fig. 9 is an enlarged perspective view which illustrates an essential portion of the displacing angle and a twist angle shown in Fig. 8; Fig. 10 is a bottom view which illustrates the mounting pitches of the attached blades of the multi-blade impeller shown in Fig. 6; Fig. 11 is an enlarged perspective view which illustrates an essential portion for the explanatory of a method of ejecting the integrally-molded multi-blade impeller shown in Fig. 2 by a conventional parallel knock pins; Fig. 12 is a perspective view which illustrates an ejector apparatus for ejecting the multi-blade impeller shown in Fig. 2 from a mold; Fig. 13 is a perspective view which illustrates a state where the multi-blade impeller shown in Fig. 2 is ejected from a lower die by an ejector block shown in Fig.

12; Fig. 14 is a partially enlarged perspective view which illustrates the multi-blade impeller shown in Fig.

13; Fig. 15 is a partially enlarged perspective view which illustrates a modification of the multi-blade impeller shown in Fig. 13; Fig. 16 is a partially-cut exploded perspective view which illustrates another transverse fan; Fig. 17 is a vertical cross sectional view which illustrates an example of a room unit for a conventional air conditioner; Fig. 18 is a perspective view which illustrates a conventional transverse fan used of the air conditioner shown in Fig. 17; Fig. 19A is a graph showing distribution of rotation noises of the conventional transverse fan shown in Fig. 18, and Figs. 19B to 19E are graphs showing distribution of rotation noises resulting in each embodiment of the present invention shown in Fig. 1; Fig. 20 is a perspective view which illustrates another conventional transverse fan; and Fig. 21 is an exploded perspective view which illustrates the transverse fan shown in Fig. 20.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described hereunder with reference to Figs. 1 to 16, in which the same reference numerals are added to the same or corresponding portions.

Fig. 1 is a perspective view which illustrates the overall structure of one a transverse fan, Fig. 2 is an exploded perspective view of Fig.

1, and Figs. 3A and 33 are detailed perspective views of Fig. 1.

A transverse fan 21 shown in Figs 1 to 3 is suitable to be incorporated in a room unit 1 (indoor unit) of an air conditioner shown in, for example, Fig. 17. A plurality of blades 24 each having a circular-arc shape horizontal cross section is concentrically and annularly disposed between a pair of right and left end plates 22 and 23 and is horizontally secured thereto while being inclined by a predetermined angle. Annular (Ring-shape) partition plates 25 are disposed at intermediate positions in the axial direction of each of the blades 24 at predetermined pitches in the axial direction. When the blades 24 are rotated around a fan axis 0, the blades 24 supply air in the axial direction.

The transverse fan 21, as shown in Fig. 2, comprises a plurality of multi-blade impellers 26 molded integrally and sequentially and concentrically secured in the axial direction thereof. The end plate 23 of the multi-blade impellers 26 disposed at the right end portion of Fig. 2 has a boss portion 27 concentrically and/or integrally formed on the outer surface of the annular partition plates 25 for detachably securing a rotational shaft S of a motor or the like with a screw or the like means.

On the other hand, an end plate 22 disposed at the left end of Fig. 2 causes the leading portion of each of the blades 24 of the mlti-blade impeller 26 disposed to the right portion in Fig. 2 to be inserted and secured within each receiving groove 22a. The end plate 22 has, at the central portion of the outer surface thereof, a projecting shaft 28 which is formed integrally or disposed integrally.

As shown in Figs. 2 and 4, each of the multi-blade impellers 26 has, on either side of the annular partition plate 25, circular-arc receiving recesses 25a for receiving and securing the leading end portions of the respective blades 24 of adjacent multi-blade impellers 26. On the other side of the partition plates 25, the plural blades 24 are, through injection molding process or the like process, integrally molded to stand upward at predetermined mounting pitches in the circumferential direction.

Each blade 24 is integrally molded with the partition plate 25 in such a manner that its horizontal cross sectional shape is formed into a circular arc inclined forwards with respect to the direction of rotation and its front end 24a in the direction of the rotation is inclined iinearly by a predetermined angle with respect to the fan axis 0. Further, each blade 24 may be integrally molded in such a manner that its front end 24b in the direction of the rotation is inclined in the form of a curve, as shown in Fig. 5.

As shown in Fig. 6 which is a bottom view and Fig. 7 which is a partially-enlarged view of Fig. 6, each blade 24 is formed into a tapered shape narrowed toward the leading portion thereof such that the thickness of the horizontal cross section is gradually reduced in a direction from a base portion 24c adjacent to the partition plate 25 toward a blade leading portion 24d, and angle a o made between tangent line Lo, which is in contact with an outline of the front end 24a connecting the front ends (external ends) of the blade base portion 24c and the blade leading portion 24d to each other and a line So perpendicular from the front end of the blade leading portion 24d to the fan axis O is 90 degrees or larger ( 6 o ? 90"), and as well as angle B i made between tangent line Li, which is in contact with the outline of a rear end 24e connecting the rear ends (internal ends) of the blade base portion 24c and the blade leading portion 24d to each other, and a line Si perpendicular from the rear end of the blade base portion 24c to the fan axis 0 is 90 degrees or larger (3 i 2 90o).

The transverse fan 21, as shown in Figs. 8 and 9, comprises each of the multi-blade impellers 26 disposed adjacently in the axial direction such that the multi-blade impellers 26 are displaced at a predetermined displacing angle 29 in a direction of, for example, the rotation thereof and they are sequentially and concentrically connected to one another.

In the structure described above, each blade 24 is formed on the partition plate 25 such that the leading portion of the front end 24a thereof is inclined by a twist angle 30 in the direction of the rotation from a perpendicular line indicated by a dashed line shown in Fig.

9, the twist angle 30 being made smaller than the aforementioned displacing angle 29.

As shown in Fig. 10, each of the multi-blade impellers 26 has an arrangement that the blades 24 on the partition plates 25 are attached at, for example, three or more mounting pitches Pa, Pb and Pc in the circumferential direction thereof.

Then, a method and an apparatus for integrally molding the multi-blade impellers 26 of the structure described above by, for example, injection molding, and then ejecting the same from a mold (a forming mold) will be described hereunder.

Hitherto, in a case where the injection-molded product is ejected from a lower die, which has been separated from an upper die of the mold, it might be feasible to employ a method comprising the step of abutting a plurality of parallel knock pins 31 against the lower surface of the partition plate 25 of the multi-blade impeller 26 to raise the lower surface. Such method, however, cannot easily eject the product from the mold because each blade 24 is inclined with respect to the partition plate at a predetermined ang'e. If the same is forcibly ejected, the blade 24 or other member will be broken.

Accordingly, the inventors of the present invention have proposed a method having the step of ejecting the multi-blade impeller 26 while rotating the same in the direction of the inclination of each blade 24 and found an ejector apparatus therefor.

Fig. 12 is a perspective view which illustrates an essential portion of an ejector apparatus 32 which comprises an ejector shaft 33, which is rotated around the axis, having a skew cam plate 34 that can be linked by a cam structure, the skew cam plate 34 being vertically moved by rotating the ejector shaft 33. The ejector shaft 33 has, at the top end thereof, an ejector block 35 connected thereto.

The ejector block 35, also as shown in Fig. 13, upwardly projects from a central hole 36a of a lower die 36 when the upper die of, for example, a mold (not shown) that can be vertically separated from each other, is separated from the lower die 36 so as to upwardly eject the multi-blade impeller 26 from the lower die 36 while rotating the same around the axis. The ejector block 35 has a disc-like mount 37.

The mount 37 forms a portion -=f the partition plate 25 for the multi-blade impeller 26 in association with the lower die 36 when the multi-blade impellers 26 are molded, the mount 37 having a circular projection 37a which forms a central hole 25b of the partition plate 25.

The projection 37a has, on the top outer surface thereof, receiving recesses 37b formed therein as shown in Fig. 14 to cause projections 25c in the form of a rectangle to be detachably received into the inner surface (the lower surface) of the partition plate 25. When the mount 37 is rotated to raise the multi-blade impeller 26 while being rotated, the multi-blade impeller 26 is able to surely follow up the mount 37. Further, each projection 25c of the partition plate 25 may be a formed as a circular hole 25d, as shown in Fig. 15, and in such case, a projection which is detachably received by each circular hole 25d must be formed on the ejector block 36 so as to project from the same.

Therefore, when the multi-blade impeller 26 is manufactured, resin material is injected into a space created by the upper die, the lower die 36 of a mold, not shown, and the mount 37 so that the multi-blade impeller 26 is molded.

Then, the upper die is separated from the lower die, and the ejector shaft 33 is moved so that the multi-blade impeller 26 is ejected from the lower die. At this time, the skew cam plate 34 rotates the ejector shaft 33 in a direction designated by an arrow A shown in Fig.

12. As a result, the ejector block 35 and the mount 37 are also rotated, causing the partition plate 25 of the molded multi-blade impeller 26 to be rotated. Hence, the multi-blade impeller 26 is ejected from the lower die 36 while being rotated.

Then, an effect of reducing nose obtainable from this embodiment will now be described with reference to Figs. 19B to 19E, which show the results obtained under the same condition as that of the test from which the test data shown in Fig. 19A has been obtained, the test data showing the noise distribution realized by the conventional example. That is, the dimensions of the transverse fan, the number of the blades 24 and the rotational speed per unit time period are the same as those of the test of the conventional transverse fan.

As shown in Fig. 1, since this transverse fan comprises each blade 24 that is inclined and thus made non-parallel with respect to the fan axis O, the pressure generated in the gap between the transverse fan 21 and the nose 9 shown in Fig. 17 and that between the transverse fan 21 and the fan casing 5 are continuously changed.

Therefore, even if the displacing angle 29 is not provided and as well as the blades 24 are disposed at the same mounting pitches in the circumferential direction, both rotation noise peak value Pa and the harmonic sound peak value Pb can be reduced as shown in Fig. 19B.

In a case where the blade 24 is inclined with respect to the fan axis 0 and as well as the displacing angle 29 is provided, the sound pressure wave, which is generated between adjacent blades 24 disposed on the two sides of the partition plate 25, is enabled to have a phase difference so as to be canceled each other due to the displacing angle 29. Therefore, the overall rotation noise, which has been reduced thanks to the inclined shape of the blade 24, can be further reduced as shown in Fig. 19C.

Further, the circumferential-directional mounting pitches of the attached plural blades 24 are set at plural kinds of pitches Pa to Pc so that the peak frequency component of the rotation noise N, which has been reduced due to the inclined shape of each blade 24, can be dispersed, as shown in Fig. 19D. Therefore, unpleasant noise can be reduced and the produced sound quality can be improved.

In a case where the circumferential-directional mounting pitches of the attached plural blades 24 are set at plural kinds of pitches Pa to Pc and as well as the displacing angle 29 is provided, the rotation noise N, which has been reduced due to the inclined shape of each blade 24, can be further reduced. Furthermore, the frequency component of the residual pitch noise of the blade can be dispersed. Therefore, unpleasant noise can be reduced and the produced sound quality can be improved.

Since this arrangement comprises the plural multi-blade impellers 26, each of which is formed by integrally molding the partition plate 25 and each blade 24, are connected and secured in the axial direction, adequate adjustment of the number of the impellers enables the overall length of the transverse fan 21 to easily be changed. Furthermore, adequate selection of the displacing angle 29 as well as enables the shape of the blade 24 to be changed easily. As a result, the manufacturing cost can be reduced.

Since the multi-blade impeller 26 is formed by integrally molding the blades 24 and the partition plate 25, the following effects will be obtainable: (1) Since the blade 24 is not required to be twisted in the post-process as has been required for the conventional example, no residual stress is generated and the strength of the blade 24 and the partition plate 25 can be improved. Furthermore, the accuracy of the dimensions of the parts, such as the mounting angle between the blade 24 and the partition plate 25, can be stabilized and improved.

Therefore, scattering in the blowing performance can be prevented.

(2) The twist angle 30 of the blade 24 can be enlarged as compared with that realized by the conventional means, thus resulting in a significant effect of eliminating noise being obtained. The conventional transverse fan 10 having the caulked structure as shown in Fig. 20 involves deterioration in the caulking strength if the twist angle is made large as described above. If leaving of distortion in the blade 11 is intended to be prevented, a flat plate must be cut into a circular arc shape. In this case, there arises a problem of waste of the material.

(3) No abnormal sound, such as blowing noise, that has been generated adjacent to the partition plate 25, is produced. That is, the transverse fan 21 inevitably encounters generation of an axial air flow on the surfaces of the blades 24, and therefore, air flow violently collides with the partition plates 25. Therefore, the conventional caulking method has usually comprises a step of creating a gap except the caulking point in order to improve the working efficiency. However, the gap raises a problem of introduction of axial-directional air flows, thus resulting in blowing noise being generated.

However, the arrangement described herein has no through gap in the partition plates 25. As a result, abnormal noise, such as blowing noise, caused from the gap can be substantially prevented.

Since the multi-blade impeller 26 is ejected from the lower die 36 while rotating the same around the axis after the injection molding process has been completed, a frictional force generated at the time of ejecting the multi-blade impeller 26 from the mold can be reduced. Therefore, an ejection process can easily be performed and the molding ability can be improved. Since each blade 24 has a shape narrowed toward the leading portion thereof, the ejection from the mold can further be facilitated.

Since the angles e o made by the tangent lines Lo and Li of the front and rear ends 24a and 24b of each blade 24 and perpendicular lines So and Si of the fan axis O are made to be 90 degrees or larger, the front and rear ends 24a and 24e do not come in contact with the mold when the multi-blade impeller 26 is ejected from the mold while being rotated. Thus, the stress of the multi-blade impeller 26 can be reduced, the strength can be improved, the wear of the mold can be prevented and the life of the mold can be lengthened.

Although the described transverse fan has the arrangement in which the blades 24 are integrally stood upward on either side of the partition plates 25, other arrangements are possible. For example, a transverse fan 41 shown in Fig. 16 may be employed, which comprises a plurality of blades 43 stood upward on the two sides of the annular partition plates 42.

Claims (2)

1. An apparatus for manufacturing a transverse fan comprising: an ejector block for supporting a partition plate in such a manner that the patition plate is ejected outward from a lower die and having a connection portion detachably connected to a connection portion of the partition plate; an ejector shaft for supporting the ejector block; and a cam plate for upwardly ejecting the ejector block while rotating the ejector block through the ejector shaft after an upper die of a mold for injection-molding the multi-blade impeller is separated from the lower die.

2. An apparatus for manufacturing a transverse fan substantially as herein described with reference to Figures 1-19 of the accompanying drawings.